1620 AUTHOR'S PREFACE Those who have taken upon them to lay down the law of nature as a thing
already searched out and understood, whether they have spoken in simple
assurance or professional affectation, have therein done philosophy and the
sciences great injury. For as they have been successful in inducing belief, so
they have been effective in quenching and stopping inquiry; and have done more
harm by spoiling and putting an end to other men's efforts than good by their
own. Those on the other hand who have taken a contrary course, and asserted that
absolutely nothing can be known — whether it were from hatred of the ancient
sophists, or from uncertainty and fluctuation of mind, or even from a kind of
fullness of learning, that they fell upon this opinion — have certainly advanced
reasons for it that are not to be despised; but yet they have neither started
from true principles nor rested in the just conclusion, zeal and affectation
having carried them much too far. The more ancient of the Greeks (whose writings
are lost) took up with better judgment a position between these two extremes —
between the presumption of pronouncing on everything, and the despair of
comprehending anything; and though frequently and bitterly complaining of the
difficulty of inquiry and the obscurity of things, and like impatient horses
champing at the bit, they did not the less follow up their object and engage
with nature, thinking (it seems) that this very question — viz., whether or not
anything can be known — was to be settled not by arguing, but by trying. And yet
they too, trusting entirely to the force of their understanding, applied no
rule, but made everything turn upon hard thinking and perpetual working and
exercise of the mind. Now my method, though hard to practice, is easy to explain; and it is this. I
propose to establish progressive stages of certainty. The evidence of the sense,
helped and guarded by a certain process of correction, I retain. But the mental
operation which follows the act of sense I for the most part reject; and instead
of it I open and lay out a new and certain path for the mind to proceed in,
starting directly from the simple sensuous perception. The necessity of this was
felt, no doubt, by those who attributed so much importance to logic, showing
thereby that they were in search of helps for the understanding, and had no
confidence in the native and spontaneous process of the mind. But this remedy
comes too late to do any good, when the mind is already, through the daily
intercourse and conversation of life, occupied with unsound doctrines and beset
on all sides by vain imaginations. And therefore that art of logic, coming (as I
said) too late to the rescue, and no way able to set matters right again, has
had the effect of fixing errors rather than disclosing truth. There remains but
one course for the recovery of a sound and healthy condition — namely, that the
entire work of the understanding be commenced afresh, and the mind itself be
from the very outset not left to take its own course, but guided at every step;
and the business be done as if by machinery. Certainly if in things mechanical
men had set to work with their naked hands, without help or force of
instruments, just as in things intellectual they have set to work with little
else than the naked forces of the understanding, very small would the matters
have been which, even with their best efforts applied in conjunction, they could
have attempted or accomplished. Now (to pause a while upon this example and look
in it as in a glass) let us suppose that some vast obelisk were (for the
decoration of a triumph or some such magnificence) to be removed from its place,
and that men should set to work upon it with their naked hands, would not any
sober spectator think them mad? And if they should then send for more people,
thinking that in that way they might manage it, would he not think them all the
madder? And if they then proceeded to make a selection, putting away the weaker
hands, and using only the strong and vigorous, would he not think them madder
than ever? And if lastly, not content with this, they resolved to call in aid
the art of athletics, and required all their men to come with hands, arms, and
sinews well anointed and medicated according to the rules of the art, would he
not cry out that they were only taking pains to show a kind of method and
discretion in their madness? Yet just so it is that men proceed in matters
intellectual — with just the same kind of mad effort and useless combination of
forces — when they hope great things either from the number and cooperation or
from the excellency and acuteness of individual wits; yea, and when they
endeavor by logic (which may be considered as a kind of athletic art) to
strengthen the sinews of the understanding, and yet with all this study and
endeavor it is apparent to any true judgment that they are but applying the
naked intellect all the time; whereas in every great work to be done by the hand
of man it is manifestly impossible, without instruments and machinery, either
for the strength of each to be exerted or the strength of all to be united. Upon these premises two things occur to me of which, that they may not be
overlooked, I would have men reminded. First, it falls out fortunately as I
think for the allaying of contradictions and heartburnings, that the honor and
reverence due to the ancients remains untouched and undiminished, while I may
carry out my designs and at the same time reap the fruit of my modesty. For if I
should profess that I, going the same road as the ancients, have something
better to produce, there must needs have been some comparison or rivalry between
us (not to be avoided by any art of words) in respect of excellency or ability
of wit; and though in this there would be nothing unlawful or new (for if there
be anything misapprehended by them, or falsely laid down, why may not I, using a
liberty common to all, take exception to it?) yet the contest, however just and
allowable, would have been an unequal one perhaps, in respect of the measure of
my own powers. As it is, however (my object being to open a new way for the
understanding, a way by them untried and unknown), the case is altered: party
zeal and emulation are at an end, and I appear merely as a guide to point out
the road — an office of small authority, and depending more upon a kind of luck
than upon any ability or excellency. And thus much relates to the persons only.
The other point of which I would have men reminded relates to the matter itself. Be it remembered then that I am far from wishing to interfere with the
philosophy which now flourishes, or with any other philosophy more correct and
complete than this which has been or may hereafter be propounded. For I do not
object to the use of this received philosophy, or others like it, for supplying
matter for disputations or ornaments for discourse — for the professor's lecture
and for the business of life. Nay, more, I declare openly that for these uses
the philosophy which I bring forward will not be much available. It does not lie
in the way. It cannot be caught up in passage. It does not flatter the
understanding by conformity with preconceived notions. Nor will it come down to
the apprehension of the vulgar except by its utility and effects. Let there be therefore (and may it be for the benefit of both) two streams
and two dispensations of knowledge, and in like manner two tribes or kindreds of
students in philosophy — tribes not hostile or alien to each other, but bound
together by mutual services; let there in short be one method for the
cultivation, another for the invention, of knowledge. And for those who prefer the former, either from hurry or from considerations
of business or for want of mental power to take in and embrace the other (which
must needs be most men's case), I wish that they may succeed to their desire in
what they are about, and obtain what they are pursuing. But if there be any man
who, not content to rest in and use the knowledge which has already been
discovered, aspires to penetrate further; to overcome, not an adversary in
argument, but nature in action; to seek, not pretty and probable conjectures,
but certain and demonstrable knowledge — I invite all such to join themselves,
as true sons of knowledge, with me, that passing by the outer courts of nature,
which numbers have trodden, we may find a way at length into her inner chambers.
And to make my meaning clearer and to familiarize the thing by giving it a name,
I have chosen to call one of these methods or ways Anticipation of the Mind,
the other Interpretation of Nature. Moreover, I have one request to make. I have on my own part made it my care
and study that the things which I shall propound should not only be true, but
should also be presented to men's minds, how strangely soever preoccupied and
obstructed, in a manner not harsh or unpleasant. It is but reasonable, however
(especially in so great a restoration of learning and knowledge), that I should
claim of men one favor in return, which is this: if anyone would form an opinion
or judgment either out of his own observation, or out of the crowd of
authorities, or out of the forms of demonstration (which have now acquired a
sanction like that of judicial laws), concerning these speculations of mine, let
him not hope that he can do it in passage or by the by; but let him examine the
thing thoroughly; let him make some little trial for himself of the way which I
describe and lay out; let him familiarize his thoughts with that subtlety of
nature to which experience bears witness; let him correct by seasonable patience
and due delay the depraved and deep-rooted habits of his mind; and when all this
is done and he has begun to be his own master, let him (if he will) use his own
judgment. APHORISMS [BOOK ONE] I Man, being the servant and interpreter of Nature, can do and understand so
much and so much only as he has observed in fact or in thought of the course of
nature. Beyond this he neither knows anything nor can do anything. II Neither the naked hand nor the understanding left to itself can effect much.
It is by instruments and helps that the work is done, which are as much wanted
for the understanding as for the hand. And as the instruments of the hand either
give motion or guide it, so the instruments of the mind supply either
suggestions for the understanding or cautions. III Human knowledge and human power meet in one; for where the cause is not known
the effect cannot be produced. Nature to be commanded must be obeyed; and that
which in contemplation is as the cause is in operation as the rule. IV Toward the effecting of works, all that man can do is to put together or put
asunder natural bodies. The rest is done by nature working within. V The study of nature with a view to works is engaged in by the mechanic, the
mathematician, the physician, the alchemist, and the magician; but by all (as
things now are) with slight endeavor and scanty success. VI It would be an unsound fancy and self-contradictory to expect that things
which have never yet been done can be done except by means which have never yet
been tried. VII The productions of the mind and hand seem very numerous in books and
manufactures. But all this variety lies in an exquisite subtlety and derivations
from a few things already known, not in the number of axioms. VIII Moreover, the works already known are due to chance and experiment rather
than to sciences; for the sciences we now possess are merely systems for the
nice ordering and setting forth of things already invented, not methods of
invention or directions for new works. IX The cause and root of nearly all evils in the sciences is this — that while
we falsely admire and extol the powers of the human mind we neglect to seek for
its true helps. X The subtlety of nature is greater many times over than the subtlety of the
senses and understanding; so that all those specious meditations, speculations,
and glosses in which men indulge are quite from the purpose, only there is no
one by to observe it. XI As the sciences which we now have do not help us in finding out new works, so
neither does the logic which we now have help us in finding out new sciences. XII The logic now in use serves rather to fix and give stability to the errors
which have their foundation in commonly received notions than to help the search
after truth. So it does more harm than good. XIII The syllogism is not applied to the first principles of sciences, and is
applied in vain to intermediate axioms, being no match for the subtlety of
nature. It commands assent therefore to the proposition, but does not take hold
of the thing. XIV The syllogism consists of propositions, propositions consist of words, words
are symbols of notions. Therefore if the notions themselves (which is the root
of the matter) are confused and overhastily abstracted from the facts, there can
be no firmness in the superstructure. Our only hope therefore lies in a true
induction. XV There is no soundness in our notions, whether logical or physical. Substance,
Quality, Action, Passion, Essence itself, are not sound notions; much less are
Heavy, Light, Dense, Rare, Moist, Dry, Generation, Corruption, Attraction,
Repulsion, Element, Matter, Form, and the like; but all are fantastical and ill
defined. XVI Our notions of less general species, as Man, Dog, Dove, and of the immediate
perceptions of the sense, as Hot, Cold, Black, White, do not materially mislead
us; yet even these are sometimes confused by the flux and alteration of matter
and the mixing of one thing with another. All the others which men have hitherto
adopted are but wanderings, not being abstracted and formed from things by
proper methods. XVII Nor is there less of willfulness and wandering in the construction of axioms
than in the formation of notions, not excepting even those very principles which
are obtained by common induction; but much more in the axioms and lower
propositions educed by the syllogism. XVIII The discoveries which have hitherto been made in the sciences are such as lie
close to vulgar notions, scarcely beneath the surface. In order to penetrate
into the inner and further recesses of nature, it is necessary that both notions
and axioms be derived from things by a more sure and guarded way, and that a
method of intellectual operation be introduced altogether better and more
certain. XIX There are and can be only two ways of searching into and discovering truth.
The one flies from the senses and particulars to the most general axioms, and
from these principles, the truth of which it takes for settled and immovable,
proceeds to judgment and to the discovery of middle axioms. And this way is now
in fashion. The other derives axioms from the senses and particulars, rising by
a gradual and unbroken ascent, so that it arrives at the most general axioms
last of all. This is the true way, but as yet untried. XX The understanding left to itself takes the same course (namely, the former)
which it takes in accordance with logical order. For the mind longs to spring up
to positions of higher generality, that it may find rest there, and so after a
little while wearies of experiment. But this evil is increased by logic, because
of the order and solemnity of its disputations. XXI The understanding left to itself, in a sober, patient, and grave mind,
especially if it be not hindered by received doctrines, tries a little that
other way, which is the right one, but with little progress, since the
understanding, unless directed and assisted, is a thing unequal, and quite unfit
to contend with the obscurity of things. XXII Both ways set out from the senses and particulars, and rest in the highest
generalities; but the difference between them is infinite. For the one just
glances at experiment and particulars in passing, the other dwells duly and
orderly among them. The one, again, begins at once by establishing certain abstract and useless
generalities, the other rises by gradual steps to that which is prior and better
known in the order of nature. XXIII There is a great difference between the Idols of the human mind and the Ideas
of the divine. That is to say, between certain empty dogmas, and the true
signatures and marks set upon the works of creation as they are found in nature. XXIV It cannot be that axioms established by argumentation should avail for the
discovery of new works, since the subtlety of nature is greater many times over
than the subtlety of argument. But axioms duly and orderly formed from
particulars easily discover the way to new particulars, and thus render sciences
active. XXV The axioms now in use, having been suggested by a scanty and manipular
experience and a few particulars of most general occurrence, are made for the
most part just large enough to fit and take these in; and therefore it is no
wonder if they do not lead to new particulars. And if some opposite instance,
not observed or not known before, chance to come in the way, the axiom is
rescued and preserved by some frivolous distinction; whereas the truer course
would be to correct the axiom itself. XXVI The conclusions of human reason as ordinarily applied in matters of nature, I
call for the sake of distinction Anticipations of Nature (as a thing rash
or premature). That reason which is elicited from facts by a just and methodical
process, I call Interpretation of Nature. XXVII Anticipations are a ground sufficiently firm for consent, for even if men
went mad all after the same fashion, they might agree one with another well
enough. XXVIII For the winning of assent, indeed, anticipations are far more powerful than
interpretations, because being collected from a few instances, and those for the
most part of familiar occurrence, they straightway touch the understanding and
fill the imagination; whereas interpretations, on the other hand, being gathered
here and there from very various and widely dispersed facts, cannot suddenly
strike the understanding; and therefore they must needs, in respect of the
opinions of the time, seem harsh and out of tune, much as the mysteries of faith
do. XXIX In sciences founded on opinions and dogmas, the use of anticipations and
logic is good; for in them the object is to command assent to the proposition,
not to master the thing. XXX Though all the wits of all the ages should meet together and combine and
transmit their labors, yet will no great progress ever be made in science by
means of anticipations; because radical errors in the first concoction of the
mind are not to be cured by the excellence of functions and subsequent remedies. XXXI It is idle to expect any great advancement in science from the superinducing
and engrafting of new things upon old. We must begin anew from the very
foundations, unless we would revolve forever in a circle with mean and
contemptible progress. XXXII The honor of the ancient authors, and indeed of all, remains untouched, since
the comparison I challenge is not of wits or faculties, but of ways and methods,
and the part I take upon myself is not that of a judge, but of a guide. XXXIII This must be plainly avowed: no judgment can be rightly formed either of my
method or of the discoveries to which it leads, by means of anticipations (that
is to say, of the reasoning which is now in use); since I cannot be called on to
abide by the sentence of a tribunal which is itself on trial. XXXIV Even to deliver and explain what I bring forward is no easy matter, for
things in themselves new will yet be apprehended with reference to what is old. XXXV It was said by Borgia of the expedition of the French into Italy, that they
came with chalk in their hands to mark out their lodgings, not with arms to
force their way in. I in like manner would have my doctrine enter quietly into
the minds that are fit and capable of receiving it; for confutations cannot be
employed when the difference is upon first principles and very notions, and even
upon forms of demonstration. XXXVI One method of delivery alone remains to us which is simply this: we must lead
men to the particulars themselves, and their series and order; while men on
their side must force themselves for a while to lay their notions by and begin
to familiarize themselves with facts. XXXVII The doctrine of those who have denied that certainty could be attained at all
has some agreement with my way of proceeding at the first setting out; but they
end in being infinitely separated and opposed. For the holders of that doctrine
assert simply that nothing can be known. I also assert that not much can be
known in nature by the way which is now in use. But then they go on to destroy
the authority of the senses and understanding; whereas I proceed to devise and
supply helps for the same. XXXVIII The idols and false notions which are now in possession of the human
understanding, and have taken deep root therein, not only so beset men's minds
that truth can hardly find entrance, but even after entrance is obtained, they
will again in the very instauration of the sciences meet and trouble us, unless
men being forewarned of the danger fortify themselves as far as may be against
their assaults. There are four classes of Idols which beset men's minds. To these for
distinction's sake I have assigned names, calling the first class
Idols of
the Tribe; the second, Idols of the Cave; the third,
Idols of the
Market Place; the fourth, Idols of the Theater. XL The formation of ideas and axioms by true induction is no doubt the proper
remedy to be applied for the keeping off and clearing away of idols. To point
them out, however, is of great use; for the doctrine of Idols is to the
interpretation of nature what the doctrine of the refutation of sophisms is to
common logic. XLI The Idols of the Tribe are inherent in human nature itself, and in
the tribe or race of men. For it is a false assertion that the human senses are
the measure of things. On the contrary, all perceptions as well of mental
sensations are according to the measure of the individual and not according to
the measure of the universe. And the human understanding is like a false mirror
which receives light irregularly, then distorts and discolors the nature of things
by mingling its own nature with it. XLII The Idols of the Cave are the idols of the individual man. For everyone
(besides the errors common to human nature in general) has a cave or den of his
own, which refracts and discolors the light of nature, owing either to his own
proper and peculiar nature; or to his education and conversation with others; or
to the reading of books, and the authority of those whom he esteems and admires;
or to the differences of impressions, accordingly as they take place in a mind
preoccupied and predisposed or in a mind indifferent and settled; or the like.
So that the spirit of man (according as it is meted out to different
individuals) is in fact a thing variable and full of perturbation, and governed
as it were by chance. Whence it was well observed by Heraclitus that men look
for sciences in their own lesser worlds, and not in the greater or common world. XLIII There are also Idols formed by the reciprocal relationships and associations of men with
each other, which I call Idols of the Market Place, on account
of the commerce and consort of men there. For it is by means of language that
men associate, and words are imposed according to the apprehension of the
vulgar. And therefore the ill and unfit choice of words wonderfully obstructs
the understanding. Nor do the definitions or explanations, concocted in certain
settings by learned men in order to guard and defend themselves, set the matter right
in any way whatsoever. But words
plainly force and overrule the understanding, and throw all into confusion, and
lead men away into numberless empty controversies and idle fancies. XLIV Lastly, there are Idols which have crept into men's minds from the various
dogmas or philosophies, and also from perverted laws of demonstration. These
I call Idols of the Theater, because in my judgment all the received systems are
but so many stage plays, representing worlds of their own creation after an
unreal and scenic fashion. Nor is it only of the systems now in vogue, or only
of the ancient sects and philosophies, that I speak; for many more plays of the
same kind may yet be composed and in like artificial manner set forth; seeing
that errors the most widely different have nevertheless causes for the most part
alike. Neither again do I mean this only of entire systems, but also of many
principles and axioms in science, which by tradition, credulity, and negligence
have come to be received. But of these several kinds of Idols I must speak more largely and exactly,
that the understanding may be duly cautioned. XLV The human understanding is of its own nature prone to suppose the existence
of more order and regularity in the world than it finds. And though there be
many things in nature which are singular and unmatched, yet it devises for them
parallels and conjugates and relatives which do not exist. Hence the fiction
that all celestial bodies move in perfect circles, spirals and dragons being
(except in name) utterly rejected. Hence too the element of fire with its orb is
brought in, to make up the square with the other three which the sense
perceives. Hence also the ratio of density of the so-called elements is
arbitrarily fixed at ten to one. And so on of other dreams. And these fancies
affect not dogmas only, but simple notions also. XLVI The human understanding when it has once adopted an opinion (either as being
the received opinion or as being agreeable to itself) draws all things else to
support and agree with it. And though there be a greater number and weight of
instances to be found on the other side, yet these it either neglects and
despises, or else by some distinction sets aside and rejects, in order that by
this great and pernicious predetermination the authority of its former
conclusions may remain inviolate. And therefore it was a good answer that was
made by one who, when they showed him hanging in a temple a picture of those who
had paid their vows as having escaped shipwreck, and would have him say whether
he did not now acknowledge the power of the gods — "Aye," asked he again, "but
where are they painted that were drowned after their vows?" And such is the way
of all superstition, whether in astrology, dreams, omens, divine judgments, or
the like; wherein men, having a delight in such vanities, mark the events where
they are fulfilled, but where they fail, though this happen much oftener,
neglect and pass them by. But with far more subtlety does this mischief
insinuate itself into philosophy and the sciences; in which the first conclusion
colors and brings into conformity with itself all that come after, though far
sounder and better. Besides, independently of that delight and vanity which I
have described, it is the peculiar and perpetual error of the human intellect to
be more moved and excited by affirmatives than by negatives; whereas it ought
properly to hold itself indifferently disposed toward both alike. Indeed, in the
establishment of any true axiom, the negative instance is the more forcible of
the two. XLVII The human understanding is moved by those things most which strike and enter
the mind simultaneously and suddenly, and so fill the imagination; and then it
feigns and supposes all other things to be somehow, though it cannot see how,
similar to those few things by which it is surrounded. But for that going to and
fro to remote and heterogeneous instances by which axioms are tried as in the
fire, the intellect is altogether slow and unfit, unless it be forced thereto by
severe laws and overruling authority. XLVIII The human understanding is unquiet; it cannot stop or rest, and still presses
onward, but in vain. Therefore it is that we cannot conceive of any end or limit
to the world, but always as of necessity it occurs to us that there is something
beyond. Neither, again, can it be conceived how eternity has flowed down to the
present day, for that distinction which is commonly received of infinity in time
past and in time to come can by no means hold; for it would thence follow that
one infinity is greater than another, and that infinity is wasting away and
tending to become finite. The like subtlety arises touching the infinite
divisibility of lines, from the same inability of thought to stop. But this
inability interferes more mischievously in the discovery of causes; for although
the most general principles in nature ought to be held merely positive, as they
are discovered, and cannot with truth be referred to a cause, nevertheless the
human understanding being unable to rest still seeks something prior in the
order of nature. And then it is that in struggling toward that which is further
off it falls back upon that which is nearer at hand, namely, on final causes,
which have relation clearly to the nature of man rather than to the nature of
the universe; and from this source have strangely defiled philosophy. But he is
no less an unskilled and shallow philosopher who seeks causes of that which is
most general, than he who in things subordinate and subaltern omits to do so. XLIX The human understanding is no dry light, but receives an infusion from the
will and affections; whence proceed sciences which may be called "sciences as
one would." For what a man had rather were true he more readily believes.
Therefore he rejects difficult things from impatience of research; sober things,
because they narrow hope; the deeper things of nature, from superstition; the
light of experience, from arrogance and pride, lest his mind should seem to be
occupied with things mean and transitory; things not commonly believed, out of
deference to the opinion of the vulgar. Numberless, in short, are the ways, and
sometimes imperceptible, in which the affections color and infect the
understanding. L But by far the greatest hindrance and aberration of the human understanding
proceeds from the dullness, incompetency, and deceptions of the senses; in that
things which strike the sense outweigh things which do not immediately strike
it, though they be more important. Hence it is that speculation commonly ceases
where sight ceases; insomuch that of things invisible there is little or no
observation. Hence all the working of the spirits enclosed in tangible bodies
lies hid and unobserved of men. So also all the more subtle changes of form in
the parts of coarser substances (which they commonly call alteration, though it
is in truth local motion through exceedingly small spaces) is in like manner
unobserved. And yet unless these two things just mentioned be searched out and
brought to light, nothing great can be achieved in nature, as far as the
production of works is concerned. So again the essential nature of our common
air, and of all bodies less dense than air (which are very many), is almost
unknown. For the sense by itself is a thing infirm and erring; neither can
instruments for enlarging or sharpening the senses do much; but all the truer
kind of interpretation of nature is effected by instances and experiments fit
and apposite; wherein the sense decides touching the experiment only, and the
experiment touching the point in nature and the thing itself. LI The human understanding is of its own nature prone to abstractions and gives
a substance and reality to things which are fleeting. But to resolve nature into
abstractions is less to our purpose than to dissect her into parts; as did the
school of Democritus, which went further into nature than the rest. Matter
rather than forms should be the object of our attention, its configurations and
changes of configuration, and simple action, and law of action or motion; for
forms are figments of the human mind, unless you will call those laws of action
forms. LII Such then are the idols which I call Idols of the Tribe, and which
take their rise either from the homogeneity of the substance of the human
spirit, or from its preoccupation, or from its narrowness, or from its restless
motion, or from an infusion of the affections, or from the incompetency of the
senses, or from the mode of impression. LIII The Idols of the Cave take their rise in the peculiar constitution,
mental or bodily, of each individual; and also in education, habit, and
accident. Of this kind there is a great number and variety. But I will instance
those the pointing out of which contains the most important caution, and which
have most effect in disturbing the clearness of the understanding. LIV Men become attached to certain particular sciences and speculations, either
because they fancy themselves the authors and inventors thereof, or because they
have bestowed the greatest pains upon them and become most habituated to them.
But men of this kind, if they betake themselves to philosophy and contemplation
of a general character, distort and color them in obedience to their former
fancies; a thing especially to be noticed in Aristotle, who made his natural
philosophy a mere bond servant to his logic, thereby rendering it contentious
and well-nigh useless. The race of chemists, again out of a few experiments of
the furnace, have built up a fantastic philosophy, framed with reference to a
few things; and Gilbert also, after he had employed himself most laboriously in
the study and observation of the loadstone, proceeded at once to construct an
entire system in accordance with his favorite subject. LV There is one principal and as it were radical distinction between different
minds, in respect of philosophy and the sciences, which is this: that some minds
are stronger and apter to mark the differences of things, others to mark their
resemblances. The steady and acute mind can fix its contemplations and dwell and
fasten on the subtlest distinctions; the lofty and discursive mind recognizes
and puts together the finest and most general resemblances. Both kinds, however,
easily err in excess, by catching the one at gradations, the other at shadows. LVI There are found some minds given to an extreme admiration of antiquity,
others to an extreme love and appetite for novelty; but few so duly tempered
that they can hold the mean, neither carping at what has been well laid down by
the ancients, nor despising what is well introduced by the moderns. This,
however, turns to the great injury of the sciences and philosophy, since these
affectations of antiquity and novelty are the humors of partisans rather than
judgments; and truth is to be sought for not in the felicity of any age, which
is an unstable thing, but in the light of nature and experience, which is
eternal. These factions therefore must be abjured, and care must be taken that
the intellect be not hurried by them into assent. LVII Contemplations of nature and of bodies in their simple form break up and
distract the understanding, while contemplations of nature and bodies in their
composition and configuration overpower and dissolve the understanding, a
distinction well seen in the school of Leucippus and Democritus as compared with
the other philosophies. For that school is so busied with the particles that it
hardly attends to the structure, while the others are so lost in admiration of
the structure that they do not penetrate to the simplicity of nature. These
kinds of contemplation should therefore be alternated and taken by turns, so
that the understanding may be rendered at once penetrating and comprehensive,
and the inconveniences above mentioned, with the idols which proceed from them,
may be avoided. LVIII Let such then be our provision and contemplative prudence for keeping off and
dislodging the Idols of the Cave, which grow for the most part either out
of the predominance of a favorite subject, or out of an excessive tendency to
compare or to distinguish, or out of partiality for particular ages, or out of
the largeness or minuteness of the objects contemplated. And generally let every
student of nature take this as a rule: that whatever his mind seizes and dwells
upon with peculiar satisfaction is to be held in suspicion, and that so much the
more care is to be taken in dealing with such questions to keep the
understanding even and clear. LIX But the Idols of the Market Place are the most troublesome of all —
idols which have crept into the understanding through the alliances of words and
names. For men believe that their reason governs words; but it is also true that
words react on the understanding; and this it is that has rendered philosophy
and the sciences sophistical and inactive. Now words, being commonly framed and
applied according to the capacity of the vulgar, follow those lines of division
which are most obvious to the vulgar understanding. And whenever an
understanding of greater acuteness or a more diligent observation would alter
those lines to suit the true divisions of nature, words stand in the way and
resist the change. Whence it comes to pass that the high and formal discussions
of learned men end oftentimes in disputes about words and names; with which
(according to the use and wisdom of the mathematicians) it would be more prudent
to begin, and so by means of definitions reduce them to order. Yet even
definitions cannot cure this evil in dealing with natural and material things,
since the definitions themselves consist of words, and those words beget others.
So that it is necessary to recur to individual instances, and those in due
series and order, as I shall say presently when I come to the method and scheme
for the formation of notions and axioms. LX The idols imposed by words on the understanding are of two kinds. They are
either names of things which do not exist (for as there are things left unnamed
through lack of observation, so likewise are there names which result from
fantastic suppositions and to which nothing in reality corresponds), or they are
names of things which exist, but yet confused and ill-defined, and hastily and
irregularly derived from realities. Of the former kind are Fortune, the Prime
Mover, Planetary Orbits, Element of Fire, and like fictions which owe their
origin to false and idle theories. And this class of idols is more easily
expelled, because to get rid of them it is only necessary that all theories
should be steadily rejected and dismissed as obsolete. But the other class, which springs out of a faulty and unskillful
abstraction, is intricate and deeply rooted. Let us take for example such a word
as humid and see how far the several things which the word is used to
signify agree with each other, and we shall find the word humid to be
nothing else than a mark loosely and confusedly applied to denote a variety of
actions which will not bear to be reduced to any constant meaning. For it both
signifies that which easily spreads itself round any other body; and that which
in itself is indeterminate and cannot solidize; and that which readily yields in
every direction; and that which easily divides and scatters itself; and that
which easily unites and collects itself; and that which readily flows and is put
in motion; and that which readily clings to another body and wets it; and that
which is easily reduced to a liquid, or being solid easily melts. Accordingly,
when you come to apply the word, if you take it in one sense, flame is humid; if
in another, air is not humid; if in another, fine dust is humid; if in another,
glass is humid. So that it is easy to see that the notion is taken by
abstraction only from water and common and ordinary liquids, without any due
verification. There are, however, in words certain degrees of distortion and error. One of
the least faulty kinds is that of names of substances, especially of lowest
species and well-deduced (for the notion of chalk and of mud is
good, of earth bad); a more faulty kind is that of actions, as to
generate, to corrupt, to alter; the most faulty is of qualities (except such
as are the immediate objects of the sense) as heavy, light, rare, dense,
and the like. Yet in all these cases some notions are of necessity a little
better than others, in proportion to the greater variety of subjects that fall
within the range of the human sense. LXI But the Idols of the Theater are not innate, nor do they steal into
the understanding secretly, but are plainly impressed and received into the mind
from the playbooks of philosophical systems and the perverted rules of
demonstration. To attempt refutations in this case would be merely inconsistent
with what I have already said, for since we agree neither upon principles nor
upon demonstrations there is no place for argument. And this is so far well,
inasmuch as it leaves the honor of the ancients untouched. For they are no wise
disparaged — the question between them and me being only as to the way. For as
the saying is, the lame man who keeps the right road outstrips the runner who
takes a wrong one. Nay, it is obvious that when a man runs the wrong way, the
more active and swift he is, the further he will go astray. But the course I propose for the discovery of sciences is such as leaves but
little to the acuteness and strength of wits, but places all wits and
understandings nearly on a level. For as in the drawing of a straight line or a
perfect circle, much depends on the steadiness and practice of the hand, if it
be done by aim of hand only, but if with the aid of rule or compass, little or
nothing; so is it exactly with my plan. But though particular confutations would
be of no avail, yet touching the sects and general divisions of such systems I
must say something; something also touching the external signs which show that
they are unsound; and finally something touching the causes of such great
infelicity and of such lasting and general agreement in error; that so the
access to truth may be made less difficult, and the human understanding may the
more willingly submit to its purgation and dismiss its idols. LXII Idols of the Theater, or of Systems, are many, and there can be and perhaps
will be yet many more. For were it not that now for many ages men's minds have
been busied with religion and theology; and were it not that civil governments,
especially monarchies, have been averse to such novelties, even in matters
speculative; so that men labor therein to the peril and harming of their
fortunes — not only unrewarded, but exposed also to contempt and envy —
doubtless there would have arisen many other philosophical sects like those
which in great variety flourished once among the Greeks. For as on the phenomena
of the heavens many hypotheses may be constructed, so likewise (and more also)
many various dogmas may be set up and established on the phenomena of
philosophy. And in the plays of this philosophical theater you may observe the
same thing which is found in the theater of the poets, that stories invented for
the stage are more compact and elegant, and more as one would wish them to be,
than true stories out of history. In general, however, there is taken for the material of philosophy either a
great deal out of a few things, or a very little out of many things; so that on
both sides philosophy is based on too narrow a foundation of experiment and
natural history, and decides on the authority of too few cases. For the Rational
School of philosophers snatches from experience a variety of common instances,
neither duly ascertained nor diligently examined and weighed, and leaves all the
rest to meditation and agitation of wit. There is also another class of philosophers who, having bestowed much
diligent and careful labor on a few experiments, have thence made bold to educe
and construct systems, wresting all other facts in a strange fashion to
conformity therewith. And there is yet a third class, consisting of those who out of faith and
veneration mix their philosophy with theology and traditions; among whom the
vanity of some has gone so far aside as to seek the origin of sciences among
spirits and genii. So that this parent stock of errors — this false philosophy —
is of three kinds: the Sophistical, the Empirical, and the Superstitious. LXIII The most conspicuous example of the first class was Aristotle, who corrupted
natural philosophy by his logic: fashioning the world out of categories;
assigning to the human soul, the noblest of substances, a genus from words of
the second intention; doing the business of density and rarity (which is to make
bodies of greater or less dimensions, that is, occupy greater or less spaces),
by the frigid distinction of act and power; asserting that single bodies have
each a single and proper motion, and that if they participate in any other, then
this results from an external cause; and imposing countless other arbitrary
restrictions on the nature of things; being always more solicitous to provide an
answer to the question and affirm something positive in words, than about the
inner truth of things; a failing best shown when his philosophy is compared with
other systems of note among the Greeks. For the homoeomera of Anaxagoras;
the Atoms of Leucippus and Democritus; the Heaven and Earth of Parmenides; the
Strife and Friendship of Empedocles; Heraclitus' doctrine how bodies are
resolved into the indifferent nature of fire, and remolded into solids, have all
of them some taste of the natural philosopher — some savor of the nature of
things, and experience, and bodies; whereas in the physics of Aristotle you hear
hardly anything but the words of logic, which in his metaphysics also, under a
more imposing name, and more forsooth as a realist than a nominalist, he has
handled over again. Nor let any weight be given to the fact that in his books on
animals and his problems, and other of his treatises, there is frequent dealing
with experiments. For he had come to his conclusion before; he did not consult
experience, as he should have done, for the purpose of framing his decisions and
axioms, but having first determined the question according to his will, he then
resorts to experience, and bending her into conformity with his placets, leads
her about like a captive in a procession. So that even on this count he is more
guilty than his modern followers, the schoolmen, who have abandoned experience
altogether. LXIV But the Empirical school of philosophy gives birth to dogmas more deformed
and monstrous than the Sophistical or Rational school. For it has its
foundations not in the light of common notions (which though it be a faint and
superficial light, is yet in a manner universal, and has reference to many
things), but in the narrowness and darkness of a few experiments. To those
therefore who are daily busied with these experiments and have infected their
imagination with them, such a philosophy seems probable and all but certain; to
all men else incredible and vain. Of this there is a notable instance in the
alchemists and their dogmas, though it is hardly to be found elsewhere in these
times, except perhaps in the philosophy of Gilbert. Nevertheless, with regard to
philosophies of this kind there is one caution not to be omitted; for I foresee
that if ever men are roused by my admonitions to betake themselves seriously to
experiment and bid farewell to sophistical doctrines, then indeed through the
premature hurry of the understanding to leap or fly to universals and principles
of things, great danger may be apprehended from philosophies of this kind,
against which evil we ought even now to prepare. LXV But the corruption of philosophy by superstition and an admixture of theology
is far more widely spread, and does the greatest harm, whether to entire systems
or to their parts. For the human understanding is obnoxious to the influence of
the imagination no less than to the influence of common notions. For the
contentious and sophistical kind of philosophy ensnares the understanding; but
this kind, being fanciful and tumid and half poetical, misleads it more by
flattery. For there is in man an ambition of the understanding, no less than of
the will, especially in high and lofty spirits. Of this kind we have among the Greeks a striking example in Pythagoras,
though he united with it a coarser and more cumbrous superstition; another in
Plato and his school, more dangerous and subtle. It shows itself likewise in
parts of other philosophies, in the introduction of abstract forms and final
causes and first causes, with the omission in most cases of causes intermediate,
and the like. Upon this point the greatest caution should be used. For nothing
is so mischievous as the apotheosis of error; and it is a very plague of the
understanding for vanity to become the object of veneration. Yet in this vanity
some of the moderns have with extreme levity indulged so far as to attempt to
found a system of natural philosophy on the first chapter of Genesis, on the
book of Job, and other parts of the sacred writings, seeking for the dead among
the living; which also makes the inhibition and repression of it the more
important, because from this unwholesome mixture of things human and divine
there arises not only a fantastic philosophy but also a heretical religion. Very
meet it is therefore that we be sober-minded, and give to faith that only which
is faith's. LXVI So much, then, for the mischievous authorities of systems, which are founded
either on common notions, or on a few experiments, or on superstition. It
remains to speak of the faulty subject matter of contemplations, especially in
natural philosophy. Now the human understanding is infected by the sight of what
takes place in the mechanical arts, in which the alteration of bodies proceeds
chiefly by composition or separation, and so imagines that something similar
goes on in the universal nature of things. From this source has flowed the
fiction of elements, and of their concourse for the formation of natural bodies.
Again, when man contemplates nature working freely, he meets with different
species of things, of animals, of plants, of minerals; whence he readily passes
into the opinion that there are in nature certain primary forms which nature
intends to educe, and that the remaining variety proceeds from hindrances and
aberrations of nature in the fulfillment of her work, or from the collision of
different species and the transplanting of one into another. To the first of
these speculations we owe our primary qualities of the elements; to the other
our occult properties and specific virtues; and both of them belong to those
empty compendia of thought wherein the mind rests, and whereby it is diverted
from more solid pursuits. It is to better purpose that the physicians bestow
their labor on the secondary qualities of matter, and the operations of
attraction, repulsion, attenuation, conspissation,1 dilatation,
astriction, dissipation, maturation, and the like; and were it not that by those
two compendia which I have mentioned (elementary qualities, to wit, and specific
virtues) they corrupted their correct observations in these other matters —
either reducing them to first qualities and their subtle and incommensurable
mixtures, or not following them out with greater and more diligent observations
to third and fourth qualities, but breaking off the scrutiny prematurely — they
would have made much greater progress. Nor are powers of this kind (I do not say
the same, but similar) to be sought for only in the medicines of the human body,
but also in the changes of all other bodies. But it is a far greater evil that they make the quiescent principles,
wherefrom, and not the moving principles, whereby, things are
produced, the object of their contemplation and inquiry. For the former tend to
discourse, the latter to works. Nor is there any value in those vulgar
distinctions of motion which are observed in the received system of natural
philosophy, as generation, corruption, augmentation, diminution, alteration, and
local motion. What they mean no doubt is this: if a body in other respects not
changed be moved from its place, this is local motion; if without change
of place or essence, it be changed in quality, this is alteration; if by
reason of the change the mass and quantity of the body do not remain the same,
this is augmentation or diminution; if they be changed to such a
degree that they change their very essence and substance and turn to something
else, this is generation and corruption. But all this is merely
popular, and does not at all go deep into nature; for these are only measures
and limits, not kinds of motion. What they intimate is how far, not by
what means, or from what source. For they do not suggest anything
with regard either to the desires of bodies or to the development of their
parts. It is only when that motion presents the thing grossly and palpably to
the sense as different from what it was that they begin to mark the division.
Even when they wish to suggest something with regard to the causes of motion,
and to establish a division with reference to them, they introduce with the
greatest negligence a distinction between motion natural and violent, a
distinction which is itself drawn entirely from a vulgar notion, since all
violent motion is also in fact natural; the external efficient simply setting
nature working otherwise than it was before. But if, leaving all this, anyone
shall observe (for instance) that there is in bodies a desire of mutual contact,
so as not to suffer the unity of nature to be quite separated or broken and a
vacuum thus made; or if anyone say that there is in bodies a desire of resuming
their natural dimensions or tension, so that if compressed within or extended
beyond them, they immediately strive to recover themselves, and fall back to
their old volume and extent; or if anyone say that there is in bodies a desire
of congregating toward masses of kindred nature — of dense bodies, for instance,
toward the globe of the earth, of thin and rare bodies toward the compass of the
sky; all these and the like are truly physical kinds of motion — but those
others are entirely logical and scholastic, as is abundantly manifest from this
comparison. Nor again is it a lesser evil that in their philosophies and contemplations
their labor is spent in investigating and handling the first principles of
things and the highest generalities of nature; whereas utility and the means of
working result entirely from things intermediate. Hence it is that men cease not
from abstracting nature till they come to potential and uninformed matter, nor
on the other hand from dissecting nature till they reach the atom; things which,
even if true, can do but little for the welfare of mankind. 1 [Conspissatio. — Ed.] LXVII A caution must also be given to the understanding against the intemperance
which systems of philosophy manifest in giving or withholding assent, because
intemperance of this kind seems to establish idols and in some sort to
perpetuate them, leaving no way open to reach and dislodge them. This excess is of two kinds: the first being manifest in those who are ready
in deciding, and render sciences dogmatic and magisterial; the other in those
who deny that we can know anything, and so introduce a wandering kind of inquiry
that leads to nothing; of which kinds the former subdues, the latter weakens the
understanding. For the philosophy of Aristotle, after having by hostile
confutations destroyed all the rest (as the Ottomans serve their brothers), has
laid down the law on all points; which done, he proceeds himself to raise new
questions of his own suggestion, and dispose of them likewise, so that nothing
may remain that is not certain and decided; a practice which holds and is in use
among his successors. The school of Plato, on the other hand, introduced Acatalepsia, at
first in jest and irony, and in disdain of the older sophists, Protagoras,
Hippias, and the rest, who were of nothing else so much ashamed as of seeming to
doubt about anything. But the New Academy made a dogma of it, and held it as a
tenet. And though theirs is a fairer seeming way than arbitrary decisions, since
they say that they by no means destroy all investigation, like Pyrrho and his
Refrainers, but allow of some things to be followed as probable, though of none
to be maintained as true; yet still when the human mind has once despaired of
finding truth, its interest in all things grows fainter, and the result is that
men turn aside to pleasant disputations and discourses and roam as it were from
object to object, rather than keep on a course of severe inquisition. But, as I
said at the beginning and am ever urging, the human senses and understanding,
weak as they are, are not to be deprived of their authority, but to be supplied
with helps. LXVIII So much concerning the several classes of Idols and their equipage; all of
which must be renounced and put away with a fixed and solemn determination, and
the understanding thoroughly freed and cleansed; the entrance into the kingdom
of man, founded on the sciences, being not much other than the entrance into the
kingdom of heaven, whereinto none may enter except as a little child. LXIX But vicious demonstrations are as the strongholds and defenses of idols; and
those we have in logic do little else than make the world the bondslave of human
thought, and human thought the bondslave of words. Demonstrations truly are in
effect the philosophies themselves and the sciences. For such as they
are, well or ill established, such are the systems of philosophy and the
contemplations which follow. Now in the whole of the process which leads from
the sense and objects to axioms and conclusions, the demonstrations which we use
are deceptive and incompetent. This process consists of four parts, and has as
many faults. In the first place, the impressions of the sense itself are faulty;
for the sense both fails us and deceives us. But its shortcomings are to be
supplied, and its deceptions to be corrected. Secondly, notions are ill-drawn
from the impressions of the senses, and are indefinite and confused, whereas
they should be definite and distinctly bounded. Thirdly, the induction is amiss
which infers the principles of sciences by simple enumeration, and does not, as
it ought, employ exclusions and solutions (or separations) of nature. Lastly,
that method of discovery and proof according to which the most general
principles are first established, and then intermediate axioms are tried and
proved by them, is the parent of error and the curse of all science. Of these
things, however, which now I do but touch upon, I will speak more largely when,
having performed these expiations and purgings of the mind, I come to set forth
the true way for the interpretation of nature. LXX But the best demonstration by far is experience, if it go not beyond the
actual experiment. For if it be transferred to other cases which are deemed
similar, unless such transfer be made by a just and orderly process, it is a
fallacious thing. But the manner of making experiments which men now use is
blind and stupid. And therefore, wandering and straying as they do with no
settled course, and taking counsel only from things as they fall out, they fetch
a wide circuit and meet with many matters, but make little progress; and
sometimes are full of hope, sometimes are distracted; and always find that there
is something beyond to be sought. For it generally happens that men make their
trials carelessly, and as it were in play; slightly varying experiments already
known, and, if the thing does not answer, growing weary and abandoning the
attempt. And even if they apply themselves to experiments more seriously and
earnestly and laboriously, still they spend their labor in working out some one
experiment, as Gilbert with the magnet, and the chemists with gold; a course of
proceeding not less unskillful in the design than small in the attempt. For no
one successfully investigates the nature of a thing in the thing itself; the
inquiry must be enlarged so as to become more general. And even when they seek to educe some science or theory from their
experiments, they nevertheless almost always turn aside with overhasty and
unseasonable eagerness to practice; not only for the sake of the uses and fruits
of the practice, but from impatience to obtain in the shape of some new work an
assurance for themselves that it is worth their while to go on; and also to show
themselves off to the world, and so raise the credit of the business in which
they are engaged. Thus, like Atalanta, they go aside to pick up the golden
apple, but meanwhile they interrupt their course, and let the victory escape
them. But in the true course of experience, and in carrying it on to the
effecting of new works, the divine wisdom and order must be our pattern. Now God
on the first day of creation created light only, giving to that work an entire
day, in which no material substance was created. So must we likewise from
experience of every kind first endeavor to discover true causes and axioms; and
seek for experiments of Light, not for experiments of Fruit. For axioms rightly
discovered and established supply practice with its instruments, not one by one,
but in clusters, and draw after them trains and troops of works. Of the paths,
however, of experience, which no less than the paths of judgment are impeded and
beset, I will speak hereafter; here I have only mentioned ordinary experimental
research as a bad kind of demonstration. But now the order of the matter in hand
leads me to add something both as to those signs which I lately mentioned
(signs that the systems of philosophy and contemplation in use are in a bad
condition), and also as to the causes of what seems at first so strange
and incredible. For a knowledge of the signs prepares assent; an explanation of
the causes removes the marvel — which two things will do much to render the
extirpation of idols from the understanding more easy and gentle. LXXI The sciences which we possess come for the most part from the Greeks. For
what has been added by Roman, Arabic, or later writers is not much nor of much
importance; and whatever it is, it is built on the foundation of Greek
discoveries. Now the wisdom of the Greeks was professorial and much given to
disputations, a kind of wisdom most adverse to the inquisition of truth. Thus
that name of Sophists, which by those who would be thought philosophers was in
contempt cast back upon and so transferred to the ancient rhetoricians, Gorgias,
Protagoras, Hippias, Polus, does indeed suit the entire class: Plato, Aristotle,
Zeno, Epicurus, Theophrastus, and their successors Chrysippus, Carneades, and
the rest. There was this difference only, that the former class was wandering
and mercenary, going about from town to town, putting up their wisdom to sale,
and taking a price for it, while the latter was more pompous and dignified, as
composed of men who had fixed abodes, and who opened schools and taught their
philosophy without reward. Still both sorts, though in other respects unequal,
were professorial; both turned the matter into disputations, and set up and
battled for philosophical sects and heresies; so that their doctrines were for
the most part (as Dionysius not unaptly rallied Plato) "the talk of idle old men
to ignorant youths." But the elder of the Greek philosophers, Empedocles,
Anaxagoras, Leucippus, Democritus, Parmenides, Heraclitus, Xenophanes, Philolaus,
and the rest (I omit Pythagoras as a mystic), did not, so far as we know, open
schools; but more silently and severely and simply — that is, with less
affectation and parade — betook themselves to the inquisition of truth. And
therefore they were in my judgment more successful; only that their works were
in the course of time obscured by those slighter persons who had more which
suits and pleases the capacity and tastes of the vulgar; time, like a river,
bringing down to us things which are light and puffed up, but letting weighty
matters sink. Still even they were not altogether free from the failing of their
nation, but leaned too much to the ambition and vanity of founding a sect and
catching popular applause. But the inquisition of truth must be despaired of
when it turns aside to trifles of this kind. Nor should we omit that judgment,
or rather divination, which was given concerning the Greeks by the Egyptian
priest — that "they were always boys, without antiquity of knowledge or
knowledge of antiquity." Assuredly they have that which is characteristic of
boys: they are prompt to prattle, but cannot generate; for their wisdom abounds
in words but is barren of works. And therefore the signs which are taken from
the origin and birthplace of the received philosophy are not good. LXXII Nor does the character of the time and age yield much better signs than the
character of the country and nation. For at that period there was but a narrow
and meager knowledge either of time or place, which is the worst thing that can
be, especially for those who rest all on experience. For they had no history
worthy to be called history that went back a thousand years — but only fables
and rumors of antiquity. And of the regions and districts of the world they knew
but a small portion, giving indiscriminately the name of Scythians to all in the
North, of Celts to all in the West; knowing nothing of Africa beyond the hither
side of Ethiopia, of Asia beyond the Ganges. Much less were they acquainted with
the provinces of the New World, even by hearsay or any well-founded rumor; nay,
a multitude of climates and zones, wherein innumerable nations breathe and live,
were pronounced by them to be uninhabitable; and the travels of Democritus,
Plato, and Pythagoras, which were rather suburban excursions than distant
journeys, were talked of as something great. In our times, on the other hand,
both many parts of the New World and the limits on every side of the Old World
are known, and our stock of experience has increased to an infinite amount.
Wherefore if (like astrologers) we draw signs from the season of their nativity
or birth, nothing great can be predicted of those systems of philosophy. LXXIII Of all signs there is none more certain or more noble than that taken from
fruits. For fruits and works are as it were sponsors and sureties for the truth
of philosophies. Now, from all these systems of the Greeks, and their
ramifications through particular sciences, there can hardly after the lapse of
so many years be adduced a single experiment which tends to relieve and benefit
the condition of man, and which can with truth be referred to the speculations
and theories of philosophy. And Celsus ingenuously and wisely owns as much when
he tells us that the experimental part of medicine was first discovered, and
that afterwards men philosophized about it, and hunted for and assigned causes;
and not by an inverse process that philosophy and the knowledge of causes led to
the discovery and development of the experimental part. And therefore it was not
strange that among the Egyptians, who rewarded inventors with divine honors and
sacred rites, there were more images of brutes than of men; inasmuch as brutes
by their natural instinct have produced many discoveries, whereas men by
discussion and the conclusions of reason have given birth to few or none. Some little has indeed been produced by the industry of chemists; but it has
been produced accidentally and in passing, or else by a kind of variation of
experiments, such as mechanics use, and not by any art or theory. For the theory
which they have devised rather confuses the experiments than aids them. They,
too, who have busied themselves with natural magic, as they call it, have but
few discoveries to show, and those trifling and imposture-like. Wherefore, as in
religion we are warned to show our faith by works, so in philosophy by the same
rule the system should be judged of by its fruits, and pronounced frivolous if
it be barren, more especially if, in place of fruits of grape and olive, it bear
thorns and briers of dispute and contention. LXXIV Signs also are to be drawn from the increase and progress of systems and
sciences. For what is founded on nature grows and increases, while what is
founded on opinion varies but increases not. If therefore those doctrines had
not plainly been like a plant torn up from its roots, but had remained attached
to the womb of nature and continued to draw nourishment from her, that could
never have come to pass which we have seen now for twice a thousand years;
namely, that the sciences stand where they did and remain almost in the same
condition, receiving no noticeable increase, but on the contrary, thriving most
under their first founder, and then declining. Whereas in the mechanical arts,
which are founded on nature and the light of experience, we see the contrary
happen, for these (as long as they are popular) are continually thriving and
growing, as having in them a breath of life, at the first rude, then convenient,
afterwards adorned, and at all times advancing. LXXV There is still another sign remaining (if sign it can be called, when it is
rather testimony, nay, of all testimony the most valid). I mean the confession
of the very authorities whom men now follow. For even they who lay down the law
on all things so confidently, do still in their more sober moods fall to
complaints of the subtlety of nature, the obscurity of things, and the weakness
of the human mind. Now if this were all they did, some perhaps of a timid
disposition might be deterred from further search, while others of a more ardent
and hopeful spirit might be whetted and incited to go on farther. But not
content to speak for themselves, whatever is beyond their own or their master's
knowledge or reach they set down as beyond the bounds of possibility, and
pronounce, as if on the authority of their art, that it cannot be known or done;
thus most presumptuously and invidiously turning the weakness of their own
discoveries into a calumny of nature herself, and the despair of the rest of the
world. Hence the school of the New Academy, which held Acatalepsia as a
tenet and doomed men to perpetual darkness. Hence the opinion that forms or true
differences of things (which are in fact laws of pure act) are past finding out
and beyond the reach of man. Hence, too, those opinions in the department of
action and operation; as, that the heat of the sun and of fire are quite
different in kind — lest men should imagine that by the operations of fire
anything like the works of nature can be educed and formed. Hence the notion
that composition only is the work of man, and mixture of none but nature — lest
men should expect from art some power of generating or transforming natural
bodies. By this sign, therefore, men will easily take warning not to mix up
their fortunes and labors with dogmas not only despaired of but dedicated to
despair. LXXVI Neither is this other sign to be omitted: that formerly there existed among
philosophers such great disagreement, and such diversities in the schools
themselves, a fact which sufficiently shows that the road from the senses to the
understanding was not skillfully laid out, when the same groundwork of
philosophy (the nature of things to wit) was torn and split up into such vague
and multifarious errors. And although in these times disagreements and
diversities of opinion on first principles and entire systems are for the most
part extinguished, still on parts of philosophy there remain innumerable
questions and disputes, so that it plainly appears that neither in the systems
themselves nor in the modes of demonstration is there anything certain or sound. LXXVII And as for the general opinion that in the philosophy of Aristotle, at any
rate, there is great agreement, since after its publication the systems of older
philosophers died away, while in the times which followed nothing better was
found, so that it seems to have been so well laid and established as to have
drawn both ages in its train — I answer in the first place, that the common
notion of the falling off of the old systems upon the publication of Aristotle's
works is a false one; for long afterwards, down even to the times of Cicero and
subsequent ages, the works of the old philosophers still remained. But in the
times which followed, when on the inundation of barbarians into the Roman empire
human learning had suffered shipwreck, then the systems of Aristotle and Plato,
like planks of lighter and less solid material, floated on the waves of time and
were preserved. Upon the point of consent also men are deceived, if the matter
be looked into more keenly. For true consent is that which consists in the
coincidence of free judgments, after due examination. But far the greater number
of those who have assented to the philosophy of Aristotle have addicted
themselves thereto from prejudgment and upon the authority of others; so that it
is a following and going along together, rather than consent. But even if it had
been a real and widespread consent, still so little ought consent to be deemed a
sure and solid confirmation, that it is in fact a strong presumption the other
way. For the worst of all auguries is from consent in matters intellectual
(divinity excepted, and politics where there is right of vote). For nothing
pleases the many unless it strikes the imagination, or binds the understanding
with the bands of common notions, as I have already said. We may very well
transfer, therefore, from moral to intellectual matters the saying of Phocion,
that if the multitude assent and applaud, men ought immediately to examine
themselves as to what blunder or fault they may have committed. This sign,
therefore, is one of the most unfavorable. And so much for this point; namely,
that the signs of truth and soundness in the received systems and sciences are
not good, whether they be drawn from their origin, or from their fruits, or from
their progress, or from the confessions of their founders, or from general
consent. LXXVIII I now come to the causes of these errors, and of so long a continuance
in them through so many ages, which are very many and very potent; that all
wonder how these considerations which I bring forward should have escaped men's
notice till now may cease, and the only wonder be how now at last they should
have entered into any man's head and become the subject of his thoughts — which
truly I myself esteem as the result of some happy accident, rather than of any
excellence of faculty in me — a birth of Time rather than a birth of Wit. Now,
in the first place, those so many ages, if you weigh the case truly, shrink into
a very small compass. For out of the five and twenty centuries over which the
memory and learning of men extends, you can hardly pick out six that were
fertile in sciences or favorable to their development. In times no less than in
regions there are wastes and deserts. For only three revolutions and periods of
learning can properly be reckoned: one among the Greeks, the second among the
Romans, and the last among us, that is to say, the nations of Western Europe.
And to each of these hardly two centuries can justly be assigned. The
intervening ages of the world, in respect of any rich or flourishing growth of
the sciences, were unprosperous. For neither the Arabians nor the Schoolmen need
be mentioned, who in the intermediate times rather crushed the sciences with a
multitude of treatises, than increased their weight. And therefore the first
cause of so meager a progress in the sciences is duly and orderly referred to
the narrow limits of the time that has been favorable to them. LXXIX In the second place there presents itself a cause of great weight in all
ways, namely, that during those very ages in which the wits and learning of men
have flourished most, or indeed flourished at all, the least part of their
diligence was given to natural philosophy. Yet this very philosophy it is that
ought to be esteemed the great mother of the sciences. For all arts and all
sciences, if torn from this root, though they may be polished and shaped and
made fit for use, yet they will hardly grow. Now it is well known that after the
Christian religion was received and grew strong, by far the greater number of
the best wits applied themselves to theology; that to this both the highest
rewards were offered, and helps of all kinds most abundantly supplied; and that
this devotion to theology chiefly occupied that third portion or epoch of time
among us Europeans of the West, and the more so because about the same time both
literature began to flourish and religious controversies to spring up. In the
age before, on the other hand, during the continuance of the second period among
the Romans, the meditations and labors of philosophers were principally employed
and consumed on moral philosophy, which to the heathen was as theology to us.
Moreover, in those times the greatest wits applied themselves very generally to
public affairs, the magnitude of the Roman empire requiring the services of a
great number of persons. Again, the age in which natural philosophy was seen to
flourish most among the Greeks was but a brief particle of time; for in early
ages the Seven Wise Men, as they were called (all except Thales), applied
themselves to morals and politics; and in later times, when Socrates had drawn
down philosophy from heaven to earth, moral philosophy became more fashionable
than ever, and diverted the minds of men from the philosophy of nature. Nay, the very period itself in which inquiries concerning nature flourished,
was by controversies and the ambitious display of new opinions corrupted and
made useless. Seeing therefore that during those three periods natural
philosophy was in a great degree either neglected or hindered, it is no wonder
if men made but small advance in that to which they were not attending. LXXX To this it may be added that natural philosophy, even among those who have
attended to it, has scarcely ever possessed, especially in these later times, a
disengaged and whole man (unless it were some monk studying in his cell, or some
gentleman in his country house), but that it has been made merely a passage and
bridge to something else. And so this great mother of the sciences has with
strange indignity been degraded to the offices of a servant, having to attend on
the business of medicine or mathematics, and likewise to wash and imbue youthful
and unripe wits with a sort of first dye, in order that they may be the fitter
to receive another afterwards. Meanwhile let no man look for much progress in
the sciences — especially in the practical part of them — unless natural
philosophy be carried on and applied to particular sciences, and particular
sciences be carried back again to natural philosophy. For want of this,
astronomy, optics, music, a number of mechanical arts, medicine itself — nay,
what one might more wonder at, moral and political philosophy, and the logical
sciences — altogether lack profoundness, and merely glide along the surface and
variety of things. Because after these particular sciences have been once
distributed and established, they are no more nourished by natural philosophy,
which might have drawn out of the true contemplation of motions, rays, sounds,
texture and configuration of bodies, affections, and intellectual perceptions,
the means of imparting to them fresh strength and growth. And therefore it is
nothing strange if the sciences grow not, seeing they are parted from their
roots. LXXXI Again there is another great and powerful cause why the sciences have made
but little progress, which is this. It is not possible to run a course aright
when the goal itself has not been rightly placed. Now the true and lawful goal
of the sciences is none other than this: that human life be endowed with new
discoveries and powers. But of this the great majority have no feeling, but are
merely hireling and professorial; except when it occasionally happens that some
workman of acuter wit and covetous of honor applies himself to a new invention,
which he mostly does at the expense of his fortunes. But in general, so far are
men from proposing to themselves to augment the mass of arts and sciences, that
from the mass already at hand they neither take nor look for anything more than
what they may turn to use in their lectures, or to gain, or to reputation, or to
some similar advantage. And if any one out of all the multitude court science
with honest affection and for her own sake, yet even with him the object will be
found to be rather the variety of contemplations and doctrines than the severe
and rigid search after truth. And if by chance there be one who seeks after
truth in earnest, yet even he will propose to himself such a kind of truth as
shall yield satisfaction to the mind and understanding in rendering causes for
things long since discovered, and not the truth which shall lead to new
assurance of works and new light of axioms. If then the end of the sciences has
not as yet been well placed, it is not strange that men have erred as to the
means. LXXXII And as men have misplaced the end and goal of the sciences, so again, even if
they had placed it right, yet they have chosen a way to it which is altogether
erroneous and impassable. And an astonishing thing it is to one who rightly
considers the matter, that no mortal should have seriously applied himself to
the opening and laying out of a road for the human understanding direct from the
sense, by a course of experiment orderly conducted and well built up, but that
all has been left either to the mist of tradition, or the whirl and eddy of
argument, or the fluctuations and mazes of chance and of vague and ill-digested
experience. Now let any man soberly and diligently consider what the way is by
which men have been accustomed to proceed in the investigation and discovery of
things, and in the first place he will no doubt remark a method of discovery
very simple and inartificial, which is the most ordinary method, and is no more
than this. When a man addresses himself to discover something, he first seeks
out and sets before him all that has been said about it by others; then he
begins to meditate for himself; and so by much agitation and working of the wit
solicits and as it were evokes his own spirit to give him oracles; which method
has no foundation at all, but rests only upon opinions and is carried about with
them. Another may perhaps call in logic to discover it for him, but that has no
relation to the matter except in name. For logical invention does not discover
principles and chief axioms, of which arts are composed, but only such things as
appear to be consistent with them. For if you grow more curious and importunate
and busy, and question her of probations and invention of principles or primary
axioms, her answer is well known; she refers you to the faith you are bound to
give to the principles of each separate art. There remains simple experience which, if taken as it comes, is called
accident; if sought for, experiment. But this kind of experience is no better
than a broom without its band, as the saying is — a mere groping, as of men in
the dark, that feel all round them for the chance of finding their way, when
they had much better wait for daylight, or light a candle, and then go. But the
true method of experience, on the contrary, first lights the candle, and then by
means of the candle shows the way; commencing as it does with experience duly
ordered and digested, not bungling or erratic, and from it educing axioms, and
from established axioms again new experiments; even as it was not without order
and method that the divine word operated on the created mass. Let men therefore
cease to wonder that the course of science is not yet wholly run, seeing that
they have gone altogether astray, either leaving and abandoning experience
entirely, or losing their way in it and wandering round and round as in a
labyrinth. Whereas a method rightly ordered leads by an unbroken route through
the woods of experience to the open ground of axioms. LXXXIII This evil, however, has been strangely increased by an opinion or conceit,
which though of long standing is vain and hurtful, namely, that the dignity of
the human mind is impaired by long and close intercourse with experiments and
particulars, subject to sense and bound in matter; especially as they are
laborious to search, ignoble to meditate, harsh to deliver, illiberal to
practice, infinite in number, and minute in subtlety. So that it has come at
length to this, that the true way is not merely deserted, but shut out and
stopped up; experience being, I do not say abandoned or badly managed, but
rejected with disdain. LXXXIV Again, men have been kept back as by a kind of enchantment from progress in
the sciences by reverence for antiquity, by the authority of men accounted great
in philosophy, and then by general consent. Of the last I have spoken above. As for antiquity, the opinion touching it which men entertain is quite a
negligent one and scarcely consonant with the word itself. For the old age of
the world is to be accounted the true antiquity; and this is the attribute of
our own times, not of that earlier age of the world in which the ancients lived,
and which, though in respect of us it was the elder, yet in respect of the world
it was the younger. And truly as we look for greater knowledge of human things
and a riper judgment in the old man than in the young, because of his experience
and of the number and variety of the things which he has seen and heard and
thought of, so in like manner from our age, if it but knew its own strength and
chose to essay and exert it, much more might fairly be expected than from the
ancient times, inasmuch as it is a more advanced age of the world, and stored
and stocked with infinite experiments and observations. Nor must it go for nothing that by the distant voyages and travels which have
become frequent in our times many things in nature have been laid open and
discovered which may let in new light upon philosophy. And surely it would be
disgraceful if, while the regions of the material globe — that is, of the earth,
of the sea, and of the stars — have been in our times laid widely open and
revealed, the intellectual globe should remain shut up within the narrow limits
of old discoveries. And with regard to authority, it shows a feeble mind to grant so much to
authors and yet deny time his rights, who is the author of authors, nay, rather
of all authority. For rightly is truth called the daughter of time, not of
authority. It is no wonder therefore if those enchantments of antiquity and
authority and consent have so bound up men's powers that they have been made
impotent (like persons bewitched) to accompany with the nature of things. LXXXV Nor is it only the admiration of antiquity, authority, and consent, that has
forced the industry of man to rest satisfied with the discoveries already made,
but also an admiration for the works themselves of which the human race has long
been in possession. For when a man looks at the variety and the beauty of the
provision which the mechanical arts have brought together for men's use, he will
certainly be more inclined to admire the wealth of man than to feel his wants;
not considering that the original observations and operations of nature (which
are the life and moving principle of all that variety) are not many nor deeply
fetched, and that the rest is but patience, and the subtle and ruled motion of
the hand and instruments — as the making of clocks (for instance) is certainly a
subtle and exact work: their wheels seem to imitate the celestial orbs, and
their alternating and orderly motion, the pulse of animals; and yet all this
depends on one or two axioms of nature. Again, if you observe the refinement of the liberal arts, or even that which
relates to the mechanical preparation of natural substances, and take notice of
such things as the discovery in astronomy of the motions of the heavens, of
harmony in music, of the letters of the alphabet (to this day not in use among
the Chinese) in grammar; or again in things mechanical, the discovery of the
works of Bacchus and Ceres — that is, of the arts of preparing wine and beer,
and of making bread; the discovery once more of the delicacies of the table, of
distillations and the like; and if you likewise bear in mind the long periods
which it has taken to bring these things to their present degree of perfection
(for they are all ancient except distillation), and again (as has been said of
clocks) how little they owe to observations and axioms of nature, and how easily
and obviously and as it were by casual suggestion they may have been discovered;
you will easily cease from wondering, and on the contrary will pity the
condition of mankind, seeing that in a course of so many ages there has been so
great a dearth and barrenness of arts and inventions. And yet these very
discoveries which we have just mentioned are older than philosophy and
intellectual arts. So that, if the truth must be spoken, when the rational and
dogmatical sciences began, the discovery of useful works came to an end. And again, if a man turn from the workshop to the library, and wonder at the
immense variety of books he sees there, let him but examine and diligently
inspect their matter and contents, and his wonder will assuredly be turned the
other way. For after observing their endless repetitions, and how men are ever
saying and doing what has been said and done before, he will pass from
admiration of the variety to astonishment at the poverty and scantiness of the
subjects which till now have occupied and possessed the minds of men. And if again he descend to the consideration of those arts which are deemed
curious rather than safe, and look more closely into the works of the alchemists
or the magicians, he will be in doubt perhaps whether he ought rather to laugh
over them or to weep. For the alchemist nurses eternal hope and when the thing
fails, lays the blame upon some error of his own; fearing either that he has not
sufficiently understood the words of his art or of his authors (whereupon he
turns to tradition and auricular whispers), or else that in his manipulations he
has made some slip of a scruple in weight or a moment in time (whereupon he
repeats his trials to infinity). And when, meanwhile, among the chances of
experiment he lights upon some conclusions either in aspect new or for utility
not contemptible, he takes these for earnest of what is to come, and feeds his
mind upon them, and magnifies them to the most, and supplies the rest in hope.
Not but that the alchemists have made a good many discoveries and presented men
with useful inventions. But their case may be well compared to the fable of the
old man who bequeathed to his sons gold buried in a vineyard, pretending not to
know the exact spot; whereupon the sons applied themselves diligently to the
digging of the vineyard, and though no gold was found there, yet the vintage by
that digging was made more plentiful. Again the students of natural magic, who explain everything by sympathies and
antipathies, have in their idle and most slothful conjectures ascribed to
substances wonderful virtues and operations; and if ever they have produced
works, they have been such as aim rather at admiration and novelty than at
utility and fruit. In superstitious magic on the other hand (if of this also we must speak), it
is especially to be observed that they are but subjects of a certain and
definite kind wherein the curious and superstitious arts, in all nations and
ages, and religions also, have worked or played. These therefore we may pass.
Meanwhile if is nowise strange if opinion of plenty has been the cause of want. LXXXVI Further, this admiration of men for knowledges and arts — an admiration in
itself weak enough, and well-nigh childish — has been increased by the craft and
artifices of those who have handled and transmitted sciences. For they set them
forth with such ambition and parade, and bring them into the view of the world
so fashioned and masked as if they were complete in all parts and finished. For
if you look at the method of them and the divisions, they seem to embrace and
comprise everything which can belong to the subject. And although these
divisions are ill filled out and are but as empty cases, still to the common
mind they present the form and plan of a perfect science. But the first and most
ancient seekers after truth were wont, with better faith and better fortune,
too, to throw the knowledge which they gathered from the contemplation of
things, and which they meant to store up for use, into aphorisms; that is, into
short and scattered sentences, not linked together by an artificial method; and
did not pretend or profess to embrace the entire art. But as the matter now is,
it is nothing strange if men do not seek to advance in things delivered to them
as long since perfect and complete. LXXXVII Moreover, the ancient systems have received no slight accession of reputation
and credit from the vanity and levity of those who have propounded new ones,
especially in the active and practical department of natural philosophy. For
there have not been wanting talkers and dreamers who, partly from credulity,
partly in imposture, have loaded mankind with promises, offering and announcing
the prolongation of life, the retardation of age, the alleviation of pain, the
repairing of natural defects, the deceiving of the senses; arts of binding and
inciting the affections, of illuminating and exalting the intellectual
faculties, of transmuting substances, of strengthening and multiplying motions
at will, of making impressions and alterations in the air, of bringing down and
procuring celestial influences; arts of divining things future, and bringing
things distant near, and revealing things secret; and many more. But with regard
to these lavish promisers, this judgment would not be far amiss: that there is
as much difference in philosophy between their vanities and true arts as there
is in history between the exploits of Julius Caesar or Alexander the Great, and
the exploits of Amadis of Gaul or Arthur of Britain. For it is true that those
illustrious generals really did greater things than these shadowy heroes are
even feigned to have done; but they did them by means and ways of action not
fabulous or monstrous. Yet surely it is not fair that the credit of true history
should be lessened because it has sometimes been injured and wronged by fables.
Meanwhile it is not to be wondered at if a great prejudice is raised against new
propositions, especially when works are also mentioned, because of those
impostors who have attempted the like; since their excess of vanity, and the
disgust it has bred, have their effect still in the destruction of all greatness
of mind in enterprises of this kind. LXXXVIII Far more, however, has knowledge suffered from littleness of spirit and the
smallness and slightness of the tasks which human industry has proposed to
itself. And what is worst of all, this very littleness of spirit comes with a
certain air of arrogance and superiority. For in the first place there is found in all arts one general device, which
has now become familiar — that the author lays the weakness of his art to the
charge of nature: whatever his art cannot attain he sets down on the authority
of the same art to be in nature impossible. And truly no art can be condemned if
it be judge itself. Moreover, the philosophy which is now in vogue embraces and
cherishes certain tenets, the purpose of which (if it be diligently examined) is
to persuade men that nothing difficult, nothing by which nature may be commanded
and subdued, can be expected from art or human labor; as with respect to the
doctrine that the heat of the sun and of fire differ in kind, and to that other
concerning mixture, has been already observed. Which things, if they be noted
accurately, tend wholly to the unfair circumscription of human power, and to a
deliberate and factitious despair, which not only disturbs the auguries of hope,
but also cuts the sinews and spur of industry, and throws away the chances of
experience itself. And all for the sake of having their art thought perfect, and
for the miserable vainglory of making it believed that whatever has not yet been
discovered and comprehended can never be discovered or comprehended hereafter. And even if a man apply himself fairly to facts, and endeavor to find out
something new, yet he will confine his aim and intention to the investigation
and working out of some one discovery and no more; such as the nature of the
magnet, the ebb and flow of the sea, the system of the heavens, and things of
this kind, which seem to be in some measure secret, and have hitherto been
handled without much success. Whereas it is most unskillful to investigate the
nature of anything in the thing itself, seeing that the same nature which
appears in some things to be latent and hidden is in others manifest and
palpable; wherefore in the former it produces wonder, in the latter excites no
attention; as we find it in the nature of consistency, which in wood or stone is
not observed, but is passed over under the appellation of solidity without
further inquiry as to why separation or solution of continuity is avoided; while
in the case of bubbles, which form themselves into certain pellicles, curiously
shaped into hemispheres, so that the solution of continuity is avoided for a
moment, it is thought a subtle matter. In fact, what in some things is accounted
a secret has in others a manifest and well-known nature, which will never be
recognized as long as the experiments and thoughts of men are engaged on the
former only. But generally speaking, in mechanics old discoveries pass for new if a man
does but refine or embellish them, or unite several in one, or couple them
better with their use, or make the work in greater or less volume than it was
before, or the like. Thus, then, it is no wonder if inventions noble and worthy of mankind have
not been brought to light, when men have been contented and delighted with such
trifling and puerile tasks, and have even fancied that in them they have been
endeavoring after, if not accomplishing, some great matter. LXXXIX Neither is it to be forgotten that in every age natural philosophy has had a
troublesome and hard to deal with adversary — namely, superstition, and the
blind and immoderate zeal of religion. For we see among the Greeks that those
who first proposed to men's then uninitiated ears the natural causes for thunder
and for storms were thereupon found guilty of impiety. Nor was much more
forbearance shown by some of the ancient fathers of the Christian church to
those who on most convincing grounds (such as no one in his senses would now
think of contradicting) maintained that the earth was round, and of consequence
asserted the existence of the antipodes. Moreover, as things now are, to discourse of nature is made harder and more
perilous by the summaries and systems of the schoolmen who, having reduced
theology into regular order as well as they were able, and fashioned it into the
shape of an art, ended in incorporating the contentious and thorny philosophy of
Aristotle, more than was fit, with the body of religion. To the same result, though in a different way, tend the speculations of those
who have taken upon them to deduce the truth of the Christian religion from the
principles of philosophers, and to confirm it by their authority, pompously
solemnizing this union of the sense and faith as a lawful marriage, and
entertaining men's minds with a pleasing variety of matter, but all the while
disparaging things divine by mingling them with things human. Now in such
mixtures of theology with philosophy only the received doctrines of philosophy
are included; while new ones, albeit changes for the better, are all but
expelled and exterminated. Lastly, you will find that by the simpleness of certain divines, access to
any philosophy, however pure, is well-nigh closed. Some are weakly afraid lest a
deeper search into nature should transgress the permitted limits of
sober-mindedness, wrongfully wresting and transferring what is said in Holy Writ
against those who pry into sacred mysteries, to the hidden things of nature,
which are barred by no prohibition. Others with more subtlety surmise and
reflect that if second causes are unknown everything can more readily be
referred to the divine hand and rod, a point in which they think religion
greatly concerned — which is in fact nothing else but to seek to gratify God
with a lie. Others fear from past example that movements and changes in
philosophy will end in assaults on religion. And others again appear
apprehensive that in the investigation of nature something may be found to
subvert or at least shake the authority of religion, especially with the
unlearned. But these two last fears seem to me to savor utterly of carnal
wisdom; as if men in the recesses and secret thought of their hearts doubted and
distrusted the strength of religion and the empire of faith over the sense, and
therefore feared that the investigation of truth in nature might be dangerous to
them. But if the matter be truly considered, natural philosophy is, after the
word of God, at once the surest medicine against superstition and the most
approved nourishment for faith, and therefore she is rightly given to religion
as her most faithful handmaid, since the one displays the will of God, the other
his power. For he did not err who said, "Ye err in that ye know not the
Scriptures and the power of God," thus coupling and blending in an indissoluble
bond information concerning his will and meditation concerning his power.
Meanwhile it is not surprising if the growth of natural philosophy is checked
when religion, the thing which has most power over men's minds, has by the
simpleness and incautious zeal of certain persons been drawn to take part
against her. XC Again, in the customs and institutions of schools, academies, colleges, and
similar bodies destined for the abode of learned men and the cultivation of
learning, everything is found adverse to the progress of science. For the
lectures and exercises there are so ordered that to think or speculate on
anything out of the common way can hardly occur to any man. And if one or two
have the boldness to use any liberty of judgment, they must undertake the task
all by themselves; they can have no advantage from the company of others. And if
they can endure this also, they will find their industry and largeness of mind
no slight hindrance to their fortune. For the studies of men in these places are
confined and as it were imprisoned in the writings of certain authors, from whom
if any man dissent he is straightway arraigned as a turbulent person and an
innovator. But surely there is a great distinction between matters of state and
the arts; for the danger from new motion and from new light is not the same. In
matters of state a change even for the better is distrusted, because it
unsettles what is established; these things resting on authority, consent, fame
and opinion, not on demonstration. But arts and sciences should be like mines,
where the noise of new works and further advances is heard on every side. But
though the matter be so according to right reason, it is not so acted on in
practice; and the points above mentioned in the administration and government of
learning put a severe restraint upon the advancement of the sciences. XCI Nay, even if that jealousy were to cease, still it is enough to check the
growth of science that efforts and labors in this field go unrewarded. For it
does not rest with the same persons to cultivate sciences and to reward them.
The growth of them comes from great wits; the prizes and rewards of them are in
the hands of the people, or of great persons, who are but in very few cases even
moderately learned. Moreover, this kind of progress is not only unrewarded with
prizes and substantial benefits; it has not even the advantage of popular
applause. For it is a greater matter than the generality of men can take in, and
is apt to be overwhelmed and extinguished by the gales of popular opinions. And
it is nothing strange if a thing not held in honor does not prosper. XCII But by far the greatest obstacle to the progress of science and to the
undertaking of new tasks and provinces therein is found in this — that men
despair and think things impossible. For wise and serious men are wont in these
matters to be altogether distrustful, considering with themselves the obscurity
of nature, the shortness of life, the deceitfulness of the senses, the weakness
of the judgment, the difficulty of experiment, and the like; and so supposing
that in the revolution of time and of the ages of the world the sciences have
their ebbs and flows; that at one season they grow and flourish, at another
wither and decay, yet in such sort that when they have reached a certain point
and condition they can advance no further. If therefore anyone believes or
promises more, they think this comes of an ungoverned and unripened mind, and
that such attempts have prosperous beginnings, become difficult as they go on,
and end in confusion. Now since these are thoughts which naturally present
themselves to men grave and of great judgment, we must take good heed that we be
not led away by our love for a most fair and excellent object to relax or
diminish the severity of our judgment. We must observe diligently what
encouragement dawns upon us and from what quarter, and, putting aside the
lighter breezes of hope, we must thoroughly sift and examine those which promise
greater steadiness and constancy. Nay, and we must take state prudence too into
our counsels, whose rule is to distrust, and to take the less favorable view of
human affairs. I am now therefore to speak touching hope, especially as I am not
a dealer in promises, and wish neither to force nor to ensnare men's judgments,
but to lead them by the hand with their good will. And though the strongest
means of inspiring hope will be to bring men to particulars, especially to
particulars digested and arranged in my Tables of Discovery (the subject partly
of the second, but much more of the fourth part of my Instauration), since this
is not merely the promise of the thing but the thing itself; nevertheless, that
everything may be done with gentleness, I will proceed with my plan of preparing
men's minds, of which preparation to give hope is no unimportant part. For
without it the rest tends rather to make men sad (by giving them a worse and
meaner opinion of things as they are than they now have, and making them more
fully to feel and know the unhappiness of their own condition) than to induce
any alacrity or to whet their industry in making trial. And therefore it is fit
that I publish and set forth those conjectures of mine which make hope in this
matter reasonable, just as Columbus did, before that wonderful voyage of his
across the Atlantic, when he gave the reasons for his conviction that new lands
and continents might be discovered besides those which were known before; which
reasons, though rejected at first, were afterwards made good by experience, and
were the causes and beginnings of great events. XCIII The beginning is from God: for the business which is in hand, having the
character of good so strongly impressed upon it, appears manifestly to proceed
from God, who is the author of good, and the Father of Lights. Now in divine
operations even the smallest beginnings lead of a certainty to their end. And as
it was said of spiritual things, "The kingdom of God cometh not with
observation," so is it in all the greater works of Divine Providence; everything
glides on smoothly and noiselessly, and the work is fairly going on before men
are aware that it has begun. Nor should the prophecy of Daniel be forgotten
touching the last ages of the world: "Many shall go to and fro, and knowledge
shall be increased"; clearly intimating that the thorough passage of the world
(which now by so many distant voyages seems to be accomplished, or in course of
accomplishment), and the advancement of the sciences, are destined by fate, that
is, by Divine Providence, to meet in the same age. XCIV Next comes a consideration of the greatest importance as an argument of hope;
I mean that drawn from the errors of past time, and of the ways hitherto
trodden. For most excellent was the censure once passed upon a government that
had been unwisely administered. "That which is the worst thing in reference to
the past, ought to be regarded as best for the future. For if you had done all
that your duty demanded, and yet your affairs were no better, you would not have
even a hope left you that further improvement is possible. But now, when your
misfortunes are owing, not to the force of circumstances, but to your own
errors, you may hope that by dismissing or correcting these errors, a great
change may be made for the better." In like manner, if during so long a course
of years men had kept the true road for discovering and cultivating sciences,
and had yet been unable to make further progress therein, bold doubtless and
rash would be the opinion that further progress is possible. But if the road
itself has been mistaken, and men's labor spent on unfit objects, it follows
that the difficulty has its rise not in things themselves, which are not in our
power, but in the human understanding, and the use and application thereof,
which admits of remedy and medicine. It will be of great use therefore to set
forth what these errors are. For as many impediments as there have been in times
past from this cause, so many arguments are there of hope for the time to come.
And although they have been partly touched before, I think fit here also, in
plain and simple words, to represent them. XCV Those who have handled sciences have been either men of experiment or men of
dogmas. The men of experiment are like the ant, they only collect and use; the
reasoners resemble spiders, who make cobwebs out of their own substance. But the
bee takes a middle course: it gathers its material from the flowers of the
garden and of the field, but transforms and digests it by a power of its own.
Not unlike this is the true business of philosophy; for it neither relies solely
or chiefly on the powers of the mind, nor does it take the matter which it
gathers from natural history and mechanical experiments and lay it up in the
memory whole, as it finds it, but lays it up in the understanding altered and
digested. Therefore from a closer and purer league between these two faculties,
the experimental and the rational (such as has never yet been made), much may be
hoped. XCVI We have as yet no natural philosophy that is pure; all is tainted and
corrupted: in Aristotle's school by logic; in Plato's by natural theology; in
the second school of Platonists, such as Proclus and others, by mathematics,
which ought only to give definiteness to natural philosophy, not to generate or
give it birth. From a natural philosophy pure and unmixed, better things are to
be expected. XCVII No one has yet been found so firm of mind and purpose as resolutely to compel
himself to sweep away all theories and common notions, and to apply the
understanding, thus made fair and even, to a fresh examination of particulars.
Thus it happens that human knowledge, as we have it, is a mere medley and
ill-digested mass, made up of much credulity and much accident, and also of the
childish notions which we at first imbibed. Now if anyone of ripe age, unimpaired senses, and well-purged mind, apply
himself anew to experience and particulars, better hopes may be entertained of
that man. In which point I promise to myself a like fortune to that of Alexander
the Great, and let no man tax me with vanity till he have heard the end; for the
thing which I mean tends to the putting off of all vanity. For of Alexander and
his deeds Aeschines spoke thus: "Assuredly we do not live the life of mortal
men; but to this end were we born, that in after ages wonders might be told of
us," as if what Alexander had done seemed to him miraculous. But in the next age
Titus Livius took a better and a deeper view of the matter, saying in effect
that Alexander "had done no more than take courage to despise vain
apprehensions." And a like judgment I suppose may be passed on myself in future
ages: that I did no great things, but simply made less account of things that
were accounted great. In the meanwhile, as I have already said, there is no hope
except in a new birth of science; that is, in raising it regularly up from
experience and building it afresh, which no one (I think) will say has yet been
done or thought of. XCVIII Now for grounds of experience — since to experience we must come — we have as
yet had either none or very weak ones; no search has been made to collect a
store of particular observations sufficient either in number, or in kind, or in
certainty, to inform the understanding, or in any way adequate. On the contrary,
men of learning, but easy withal and idle, have taken for the construction or
for the confirmation of their philosophy certain rumors and vague fames or airs
of experience, and allowed to these the weight of lawful evidence. And just as
if some kingdom or state were to direct its counsels and affairs not by letters
and reports from ambassadors and trustworthy messengers, but by the gossip of
the streets; such exactly is the system of management introduced into philosophy
with relation to experience. Nothing duly investigated, nothing verified,
nothing counted, weighed, or measured, is to be found in natural history; and
what in observation is loose and vague, is in information deceptive and
treacherous. And if anyone thinks that this is a strange thing to say, and
something like an unjust complaint, seeing that Aristotle, himself so great a
man, and supported by the wealth of so great a king, has composed so accurate a
history of animals; and that others with greater diligence, though less
pretense, have made many additions; while others, again, have compiled copious
histories and descriptions of metals, plants, and fossils; it seems that he does
not rightly apprehend what it is that we are now about. For a natural history
which is composed for its own sake is not like one that is collected to supply
the understanding with information for the building up of philosophy. They
differ in many ways, but especially in this: that the former contains the
variety of natural species only, and not experiments of the mechanical arts. For
even as in the business of life a man's disposition and the secret workings of
his mind and affections are better discovered when he is in trouble than at
other times, so likewise the secrets of nature reveal themselves more readily
under the vexations of art than when they go their own way. Good hopes may
therefore be conceived of natural philosophy, when natural history, which is the
basis and foundation of it, has been drawn up on a better plan; but not till
then. XCIX Again, even in the great plenty of mechanical experiments, there is yet a
great scarcity of those which are of most use for the information of the
understanding. For the mechanic, not troubling himself with the investigation of
truth, confines his attention to those things which bear upon his particular
work, and will not either raise his mind or stretch out his hand for anything
else. But then only will there be good ground of hope for the further advance of
knowledge when there shall be received and gathered together into natural
history a variety of experiments which are of no use in themselves but simply
serve to discover causes and axioms, which I call Experimenta lucifera,
experiments of light, to distinguish them from those which I call
fructifera, experiments of fruit. Now experiments of this kind have one admirable property and condition: they
never miss or fail. For since they are applied, not for the purpose of producing
any particular effect, but only of discovering the natural cause of some effect,
they answer the end equally well whichever way they turn out; for they settle
the question. C But not only is a greater abundance of experiments to be sought for and
procured, and that too of a different kind from those hitherto tried; an
entirely different method, order, and process for carrying on and advancing
experience must also be introduced. For experience, when it wanders in its own
track, is, as I have already remarked, mere groping in the dark, and confounds
men rather than instructs them. But when it shall proceed in accordance with a
fixed law, in regular order, and without interruption, then may better things be
hoped of knowledge. CI But even after such a store of natural history and experience as is required
for the work of the understanding, or of philosophy, shall be ready at hand,
still the understanding is by no means competent to deal with it offhand and by
memory alone; no more than if a man should hope by force of memory to retain and
make himself master of the computation of an ephemeris. And yet hitherto more
has been done in matter of invention by thinking than by writing; and experience
has not yet learned her letters. Now no course of invention can be satisfactory
unless it be carried on in writing. But when this is brought into use, and
experience has been taught to read and write, better things may be hoped. CII Moreover, since there is so great a number and army of particulars, and that
army so scattered and dispersed as to distract and confound the understanding,
little is to be hoped for from the skirmishings and slight attacks and desultory
movements of the intellect, unless all the particulars which pertain to the
subject of inquiry shall, by means of Tables of Discovery, apt, well arranged,
and, as it were, animate, be drawn up and marshaled; and the mind be set to work
upon the helps duly prepared and digested which these tables supply. CIII But after this store of particulars has been set out duly and in order before
our eyes, we are not to pass at once to the investigation and discovery of new
particulars or works; or at any rate if we do so we must not stop there. For
although I do not deny that when all the experiments of all the arts shall have
been collected and digested, and brought within one man's knowledge and
judgment, the mere transferring of the experiments of one art to others may
lead, by means of that experience which I term literate, to the discovery of
many new things of service to the life and state of man, yet it is no great
matter that can be hoped from that; but from the new light of axioms, which
having been educed from those particulars by a certain method and rule, shall in
their turn point out the way again to new particulars, greater things may be
looked for. For our road does not lie on a level, but ascends and descends;
first ascending to axioms, then descending to works. CIV The understanding must not, however, be allowed to jump and fly from
particulars to axioms remote and of almost the highest generality (such as the
first principles, as they are called, of arts and things), and taking stand upon
them as truths that cannot be shaken, proceed to prove and frame the middle
axioms by reference to them; which has been the practice hitherto, the
understanding being not only carried that way by a natural impulse, but also by
the use of syllogistic demonstration trained and inured to it. But then, and
then only, may we hope well of the sciences when in a just scale of ascent, and
by successive steps not interrupted or broken, we rise from particulars to
lesser axioms; and then to middle axioms, one above the other; and last of all
to the most general. For the lowest axioms differ but slightly from bare
experience, while the highest and most general (which we now have) are notional
and abstract and without solidity. But the middle are the true and solid and
living axioms, on which depend the affairs and fortunes of men; and above them
again, last of all, those which are indeed the most general; such, I mean, as
are not abstract, but of which those intermediate axioms are really limitations. The understanding must not therefore be supplied with wings, but rather hung
with weights, to keep it from leaping and flying. Now this has never yet been
done; when it is done, we may entertain better hopes of the sciences. CV In establishing axioms, another form of induction must be devised than has
hitherto been employed, and it must be used for proving and discovering not
first principles (as they are called) only, but also the lesser axioms, and the
middle, and indeed all. For the induction which proceeds by simple enumeration
is childish; its conclusions are precarious and exposed to peril from a
contradictory instance; and it generally decides on too small a number of facts,
and on those only which are at hand. But the induction which is to be available
for the discovery and demonstration of sciences and arts, must analyze nature by
proper rejections and exclusions; and then, after a sufficient number of
negatives, come to a conclusion on the affirmative instances — which has not yet
been done or even attempted, save only by Plato, who does indeed employ this
form of induction to a certain extent for the purpose of discussing definitions
and ideas. But in order to furnish this induction or demonstration well and duly
for its work, very many things are to be provided which no mortal has yet
thought of; insomuch that greater labor will have to be spent in it than has
hitherto been spent on the syllogism. And this induction must be used not only
to discover axioms, but also in the formation of notions. And it is in this
induction that our chief hope lies. CVI But in establishing axioms by this kind of induction, we must also examine
and try whether the axiom so established be framed to the measure of those
particulars only from which it is derived, or whether it be larger and wider.
And if it be larger and wider, we must observe whether by indicating to us new
particulars it confirm that wideness and largeness as by a collateral security,
that we may not either stick fast in things already known, or loosely grasp at
shadows and abstract forms, not at things solid and realized in matter. And when
this process shall have come into use, then at last shall we see the dawn of a
solid hope. CVII And here also should be remembered what was said above concerning the
extending of the range of natural philosophy to take in the particular sciences,
and the referring or bringing back of the particular sciences to natural
philosophy, that the branches of knowledge may not be severed and cut off from
the stem. For without this the hope of progress will not be so good. CVIII So much then for the removing of despair and the raising of hope through the
dismissal or rectification of the errors of past time. We must now see what else
there is to ground hope upon. And this consideration occurs at once — that if
many useful discoveries have been made by accident or upon occasion, when men
were not seeking for them but were busy about other things, no one can doubt but
that when they apply themselves to seek and make this their business, and that
too by method and in order and not by desultory impulses, they will discover far
more. For although it may happen once or twice that a man shall stumble on a
thing by accident which, when taking great pains to search for it, he could not
find, yet upon the whole it unquestionably falls out the other way. And
therefore far better things, and more of them, and at shorter intervals, are to
be expected from man's reason and industry and direction and fixed application
than from accident and animal instinct and the like, in which inventions have
hitherto had their origin. CIX Another argument of hope may be drawn from this — that some of the inventions
already known are such as before they were discovered it could hardly have
entered any man's head to think of; they would have been simply set aside as
impossible. For in conjecturing what may be men set before them the example of
what has been, and divine of the new with an imagination preoccupied and colored
by the old; which way of forming opinions is very fallacious, for streams that
are drawn from the springheads of nature do not always run in the old channels. If, for instance, before the invention of ordnance, a man had described the
thing by its effects, and said that there was a new invention by means of which
the strongest towers and walls could be shaken and thrown down at a great
distance, men would doubtless have begun to think over all the ways of
multiplying the force of catapults and mechanical engines by weights and wheels
and such machinery for ramming and projecting; but the notion of a fiery blast
suddenly and violently expanding and exploding would hardly have entered into
any man's imagination or fancy, being a thing to which nothing immediately
analogous had been seen, except perhaps in an earthquake or in lightning, which
as magnalia or marvels of nature, and by man not imitable, would have
been immediately rejected. In the same way, if, before the discovery of silk, anyone had said that there
was a kind of thread discovered for the purposes of dress and furniture which
far surpassed the thread of linen or of wool in fineness and at the same time in
strength, and also in beauty and softness, men would have begun immediately to
think of some silky kind of vegetable, or of the finer hair of some animal, or
of the feathers and down of birds; but a web woven by a tiny worm, and that in
such abundance, and renewing itself yearly, they would assuredly never have
thought. Nay, if anyone had said anything about a worm, he would no doubt have
been laughed at as dreaming of a new kind of cobwebs. So again, if, before the discovery of the magnet, anyone had said that a
certain instrument had been invented by means of which the quarters and points
of the heavens could be taken and distinguished with exactness, men would have
been carried by their imagination to a variety of conjectures concerning the
more exquisite construction of astronomical instruments; but that anything could
be discovered agreeing so well in its movements with the heavenly bodies, and
yet not a heavenly body itself, but simply a substance of metal or stone, would
have been judged altogether incredible. Yet these things and others like them
lay for so many ages of the world concealed from men, nor was it by philosophy
or the rational arts that they were found out at last, but by accident and
occasion, being indeed, as I said, altogether different in kind and as remote as
possible from anything that was known before; so that no preconceived notion
could possibly have led to the discovery of them. There is therefore much ground for hoping that there are still laid up in the
womb of nature many secrets of excellent use, having no affinity or parallelism
with anything that is now known, but lying entirely out of the beat of the
imagination, which have not yet been found out. They too no doubt will some time
or other, in the course and revolution of many ages, come to light of
themselves, just as the others did; only by the method of which we are now
treating they can be speedily and suddenly and simultaneously presented and
anticipated. CX But we have also discoveries to show of another kind, which prove that noble
inventions may be lying at our very feet, and yet mankind may step over without
seeing them. For however the discovery of gunpowder, of silk, of the magnet, of
sugar, of paper, or the like, may seem to depend on certain properties of things
themselves and nature, there is at any rate nothing in the art of printing which
is not plain and obvious. Nevertheless for want of observing that although it is
more difficult to arrange types of letters than to write letters by the motion
of the hand, there is yet this difference between the two, that types once
arranged serve for innumerable impressions, but letters written with the hand
for a single copy only; or perhaps again for want of observing that ink can be
so thickened as to color without running (particularly when the letters face
upwards and the impression is made from above) — for want, I say, of observing
these things, men went for so many ages without this most beautiful discovery,
which is of so much service in the propagation of knowledge. But such is the infelicity and unhappy disposition of the human mind in this
course of invention, that it first distrusts and then despises itself: first
will not believe that any such thing can be found out; and when it is found out,
cannot understand how the world should have missed it so long. And this very
thing may be justly taken as an argument of hope, namely, that there is a great
mass of inventions still remaining which not only by means of operations that
are yet to be discovered, but also through the transferring, comparing, and
applying of those already known, by the help of that learned experience of which
I spoke, may be deduced and brought to light. CXI There is another ground of hope that must not be omitted. Let men but think
over their infinite expenditure of understanding, time, and means on matters and
pursuits of far less use and value; whereof, if but a small part were directed
to sound and solid studies, there is no difficulty that might not be overcome.
This I thought good to add, because I plainly confess that a collection of
history natural and experimental, such as I conceive it and as it ought to be,
is a great, I may say a royal work, and of much labor and expense. CXII Meantime, let no man be alarmed at the multitude of particulars, but let this
rather encourage him to hope. For the particular phenomena of art and nature are
but a handful to the inventions of the wit, when disjoined and separated from
the evidence of things. Moreover, this road has an issue in the open ground and
not far off; the other has no issue at all, but endless entanglement. For men
hitherto have made but short stay with experience, but passing her lightly by,
have wasted an infinity of time on meditations and glosses of the wit. But if
someone were by that could answer our questions and tell us in each case what
the fact in nature is, the discovery of all causes and sciences would be but the
work of a few years. CXIII Moreover, I think that men may take some hope from my own example. And this I
say not by way of boasting, but because it is useful to say it. If there be any
that despond, let them look at me, that being of all men of my time the most
busied in affairs of state, and a man of health not very strong (whereby much
time is lost), and in this course altogether a pioneer, following in no man's
track nor sharing these counsels with anyone, have nevertheless by resolutely
entering on the true road, and submitting my mind to Things, advanced these
matters, as I suppose, some little way. And then let them consider what may be
expected (after the way has been thus indicated) from men abounding in leisure,
and from association of labors, and from successions of ages — the rather
because it is not a way over which only one man can pass at a time (as is the
case with that of reasoning), but one in which the labors and industries of men
(especially as regards the collecting of experience) may with the best effect be
first distributed and then combined. For then only will men begin to know their
strength when instead of great numbers doing all the same things, one shall take
charge of one thing and another of another. CXIV Lastly, even if the breath of hope which blows on us from that New Continent
were fainter than it is and harder to perceive, yet the trial (if we would not
bear a spirit altogether abject) must by all means be made. For there is no
comparison between that which we may lose by not trying and by not succeeding,
since by not trying we throw away the chance of an immense good; by not
succeeding we only incur the loss of a little human labor. But as it is, it
appears to me from what has been said, and also from what has been left unsaid,
that there is hope enough and to spare, not only to make a bold man try, but
also to make a sober-minded and wise man believe. CXV Concerning the grounds then for putting away despair, which has been one of
the most powerful causes of delay and hindrance to the progress of knowledge, I
have now spoken. And this also concludes what I had to say touching the signs
and causes of the errors, sluggishness, and ignorance which have prevailed;
especially since the more subtle causes, which do not fall under popular
judgment and observation, must be referred to what has been said on the Idols of
the human mind. And here likewise should close that part of my Instauration which is devoted
to pulling down, which part is performed by three refutations: first, by the
refutation of the natural human reason, left to itself; secondly, by the
refutation of the demonstrations; and thirdly, by the refutation of the
theories, or the received systems of philosophy and doctrine. And the
refutation of these has been such as alone it could be: that is to say, by signs
and the evidence of causes, since no other kind of confutation was open to me,
differing as I do from the others both on first principles and on rules of
demonstration. It is time therefore to proceed to the art itself and rule of interpreting
nature. Still, however, there remains something to be premised. For whereas in
this first book of aphorisms I proposed to prepare men's minds as well for
understanding as for receiving what is to follow, now that I have purged and
swept and leveled the floor of the mind, it remains that I place the mind in a
good position and as it were in a favorable aspect toward what I have to lay
before it. For in a new matter it is not only the strong preoccupation of some
old opinion that tends to create a prejudice, but also a false preconception or
prefiguration of the new thing which is presented. I will endeavor therefore to
impart sound and true opinions as to the things I propose, although they are to
serve only for the time, and by way of interest (so to speak), till the thing
itself, which is the principal, be fully known. CXVI First, then, I must request men not to suppose that after the fashion of
ancient Greeks, and of certain moderns, as Telesius, Patricius, Severinus, I
wish to found a new sect in philosophy. For this is not what I am about, nor do
I think that it matters much to the fortunes of men what abstract notions one
may entertain concerning nature and the principles of things. And no doubt many
old theories of this kind can be revived and many new ones introduced, just as
many theories of the heavens may be supposed which agree well enough with the
phenomena and yet differ with each other. But for my part I do not trouble myself with any such speculative and withal
unprofitable matters. My purpose, on the contrary, is to try whether I cannot in
very fact lay more firmly the foundations and extend more widely the limits of
the power and greatness of man. And although on some special subjects and in an
incomplete form I am in possession of results which I take to be far more true
and more certain and withal more fruitful than those now received (and these I
have collected into the fifth part of my Instauration), yet I have no entire or
universal theory to propound. For it does not seem that the time is come for
such an attempt. Neither can I hope to live to complete the sixth part of the
Instauration (which is destined for the philosophy discovered by the legitimate
interpretation of nature), but hold it enough if in the intermediate business I
bear myself soberly and profitably, sowing in the meantime for future ages the
seeds of a purer truth, and performing my part toward the commencement of the
great undertaking. CXVII And as I do not seek to found a school, so neither do I hold out offers or
promises of particular works. It may be thought, indeed, that I who make such
frequent mention of works and refer everything to that end, should produce some
myself by way of earnest. But my course and method, as I have often clearly
stated and would wish to state again, is this — not to extract works from works
or experiments from experiments (as an empiric), but from works and experiments
to extract causes and axioms, and again from those causes and axioms new works
and experiments, as a legitimate interpreter of nature. And although in my
tables of discovery (which compose the fourth part of the Instauration), and
also in the examples of particulars (which I have adduced in the second part),
and moreover in my observations on the history (which I have drawn out in the
third part), any reader of even moderate sagacity and intelligence will
everywhere observe indications and outlines of many noble works; still I
candidly confess that the natural history which I now have, whether collected
from books or from my own investigations, is neither sufficiently copious nor
verified with sufficient accuracy to serve the purposes of legitimate
interpretation. Accordingly, if there be anyone more apt and better prepared for mechanical
pursuits, and sagacious in hunting out works by the mere dealing with
experiment, let him by all means use his industry to gather from my history and
tables many things by the way, and apply them to the production of works, which
may serve as interest until the principal be forthcoming. But for myself, aiming
as I do at greater things, I condemn all unseasonable and premature tarrying
over such things as these, being (as I often say) like Atalanta's balls. For I
do not run off like a child after golden apples, but stake all on the victory of
art over nature in the race. Nor do I make haste to mow down the moss or the
corn in blade, but wait for the harvest in its due season. CXVIII There will be found, no doubt, when ray history and tables of discovery are
read, some things in the experiments themselves that are not quite certain, or
perhaps that are quite false, which may make a man think that the foundations
and principles upon which my discoveries rest are false and doubtful. But this
is of no consequence, for such things must needs happen at first. It is only
like the occurrence in a written or printed page of a letter or two mistaken or
misplaced, which does not much hinder the reader, because such errors are easily
corrected by the sense. So likewise may there occur in my natural history many
experiments which are mistaken and falsely set down, and yet they will
presently, by the discovery of causes and axioms, be easily expunged and
rejected. It is nevertheless true that if the mistakes in natural history and
experiments are important, frequent, and continual, they cannot possibly be
corrected or amended by any felicity of wit or art. And therefore, if in my
natural history, which has been collected and tested with so much diligence,
severity, and I may say religious care, there still lurk at intervals certain
falsities or errors in the particulars, what is to be said of common natural
history, which in comparison with mine is so negligent and inexact? And what of
the philosophy and sciences built on such a sand (or rather quicksand)? Let no
man therefore trouble himself for this. CXIX There will be met with also in my history and experiments many things which
are trivial and commonly known; many which are mean and low; many, lastly, which
are too subtle and merely speculative, and that seem to be of no use; which kind
of things may possibly avert and alienate men's interest. And first, for those things which seem common. Let men bear in mind that
hitherto they have been accustomed to do no more than refer and adapt the causes
of things which rarely happen to such as happen frequently, while of those which
happen frequently they never ask the cause, but take them as they are for
granted. And therefore they do not investigate the causes of weight, of the
rotation of heavenly bodies, of heat, cold, light, hardness, softness, rarity,
density, liquidity, solidity, animation, inanimation, similarity, dissimilarity,
organization, and the like; but admitting these as self-evident and obvious,
they dispute and decide on other things of less frequent and familiar
occurrence. But I, who am well aware that no judgment can be passed on uncommon or
remarkable things, much less anything new brought to light, unless the causes of
common things, and the causes of those causes, be first duly examined and found
out, am of necessity compelled to admit the commonest things into my history.
Nay, in my judgment philosophy has been hindered by nothing more than this, that
things of familiar and frequent occurrence do not arrest and detain the thoughts
of men, but are received in passing without any inquiry into their causes;
insomuch that information concerning things which are not known is not oftener
wanted than attention concerning things which are. CXX And for things that are mean or even filthy — things which (as Pliny says)
must be introduced with an apology — such things, no less than the most splendid
and costly, must be admitted into natural history. Nor is natural history
polluted thereby, for the sun enters the sewer no less than the palace, yet
takes no pollution. And for myself, I am not raising a capitol or pyramid to the
pride of man, but laying a foundation in the human understanding for a holy
temple after the model of the world. That model therefore I follow. For whatever
deserves to exist deserves also to be known, for knowledge is the image of
existence; and things mean and splendid exist alike. Moreover, as from certain
putrid substances — musk, for instance, and civet — the sweetest odors are
sometimes generated, so, too, from mean and sordid instances there sometimes
emanates excellent light and information. But enough and more than enough of
this, such fastidiousness being merely childish and effeminate. CXXI But there is another objection which must be more carefully looked to,
namely, that there are many things in this History which to common apprehension,
or indeed to any understanding accustomed to the present system, will seem to be
curiously and unprofitably subtle. Upon this point, therefore, above all I must
say again what I have said already: that at first, and for a time, I am seeking
for experiments of light, not for experiments of fruit, following therein, as I
have often said, the example of the divine creation which on the first day
produced light only, and assigned to it alone one entire day, nor mixed up with
it on that day any material work. To suppose, therefore, that things like these are of no use is the same as to
suppose that light is of no use, because it is not a thing solid or material.
And the truth is that the knowledge of simple natures well examined and defined
is as light: it gives entrance to all the secrets of nature's workshop, and
virtually includes and draws after it whole bands and troops of works, and opens
to us the sources of the noblest axioms; and yet in itself it is of no great
use. So also the letters of the alphabet in themselves and apart have no use or
meaning, yet they are the subject matter for the composition and apparatus of
all discourse. So again the seeds of things are of much latent virtue, and yet
of no use except in their development. And the scattered rays of light itself,
until they are made to converge, can impart none of their benefit. But if objection be taken to speculative subtleties, what is to be said of
the schoolmen, who have indulged in subtleties to such excess — in subtleties,
too, that were spent on words, or at any rate on popular notions (which is much
the same thing), not on facts or nature; and such as were useless not only in
their origin but also in their consequences; and not like those I speak of,
useless indeed for the present, but promising infinite utility hereafter. But
let men be assured of this, that all subtlety of disputation and discourse, if
not applied till after axioms are discovered, is out of season and preposterous,
and that the true and proper or at any rate the chief time for subtlety is in
weighing experience and in founding axioms thereon. For that other subtlety,
though it grasps and snatches at nature, yet can never take hold of her.
Certainly what is said of opportunity or fortune is most true of nature: she has
a lock in front, but is bald behind. Lastly, concerning the disdain to receive into natural history things either
common, or mean, or oversubtle and in their original condition useless, the
answer of the poor woman to the haughty prince who had rejected her petition as
an unworthy thing and beneath his dignity, may be taken for an oracle: "Then
leave off being king." For most certain it is that he who will not attend to
things like these as being too paltry and minute, can neither win the kingdom of
nature nor govern it. CXXII It may be thought also a strange and a harsh thing that we should at once and
with one blow set aside all sciences and all authors; and that, too, without
calling in any of the ancients to our aid and support, but relying on our own
strength. And I know that if I had chosen to deal less sincerely, I might easily have
found authority for my suggestions by referring them either to the old times
before the Greeks (when natural science was perhaps more flourishing, though it
made less noise, not having yet passed into the pipes and trumpets of the
Greeks), or even, in part at least, to some of the Greeks themselves; and so
gained for them both support and honor, as men of no family devise for
themselves by the good help of genealogies the nobility of a descent from some
ancient stock. But for my part, relying on the evidence and truth of things, I
reject all forms of fiction and imposture; nor do I think that it matters any
more to the business in hand whether the discoveries that shall now be made were
long ago known to the ancients, and have their settings and their risings
according to the vicissitude of things and course of ages, than it matters to
mankind whether the new world be that island of Atlantis with which the ancients
were acquainted, or now discovered for the first time. For new discoveries must
be sought from the light of nature, not fetched back out of the darkness of
antiquity. And as for the universality of the censure, certainly if the matter be truly
considered such a censure is not only more probable but more modest, too, than a
partial one would be. For if the errors had not been rooted in primary notions,
there must have been some true discoveries to correct the false. But the errors
being fundamental, and not so much of false judgment as of inattention and
oversight, it is no wonder that men have not obtained what they have not tried
for, nor reached a mark which they never set up, nor finished a course which
they never entered on or kept. And as for the presumption implied in it, certainly if a man undertakes by
steadiness of hand and power of eye to describe a straighter line or more
perfect circle than anyone else, he challenges a comparison of abilities; but if
he only says that he with the help of a rule or a pair of compasses can draw a
straighter line or a more perfect circle than anyone else can by eye and hand
alone, he makes no great boast. And this remark, be it observed, applies not
merely to this first and inceptive attempt of mine, but to all that shall take
the work in hand hereafter. For my way of discovering sciences goes far to level
men's wit and leaves but little to individual excellence, because it performs
everything by the surest rules and demonstrations. And therefore I attribute my
part in all this, as I have often said, rather to good luck than to ability, and
account it a birth of time rather than of wit. For certainly chance has
something to do with men's thoughts, as well as with their works and deeds. CXXIII I may say then of myself that which one said in jest (since it marks the
distinction so truly), "It cannot be that we should think alike, when one drinks
water and the other drinks wine." Now other men, as well in ancient as in modern
times, have in the matter of sciences drunk a crude liquor like water, either
flowing spontaneously from the understanding, or drawn up by logic, as by wheels
from a well. Whereas I pledge mankind in a liquor strained from countless
grapes, from grapes ripe and fully seasoned, collected in clusters, and
gathered, and then squeezed in the press, and finally purified and clarified in
the vat. And therefore it is no wonder if they and I do not think alike. CXXIV Again, it will be thought, no doubt, that the goal and mark of knowledge
which I myself set up (the very point which I object to in others) is not the
true or the best, for that the contemplation of truth is a thing worthier and
loftier than all utility and magnitude of works; and that this long and anxious
dwelling with experience and matter and the fluctuations of individual things,
drags down the mind to earth, or rather sinks it to a very Tartarus of turmoil
and confusion, removing and withdrawing it from the serene tranquility of
abstract wisdom, a condition far more heavenly. Now to this I readily assent,
and indeed this which they point at as so much to be preferred is the very thing
of all others which I am about. For I am building in the human understanding a
true model of the world, such as it is in fact, not such as a man's own reason
would have it to be; a thing which cannot be done without a very diligent
dissection and anatomy of the world. But I say that those foolish and apish
images of worlds which the fancies of men have created in philosophical systems
must be utterly scattered to the winds. Be it known then how vast a difference
there is (as I said above) between the idols of the human mind and the ideas of
the divine. The former are nothing more than arbitrary abstractions; the latter
are the Creator's own stamp upon creation, impressed and defined in matter by
true and exquisite lines. Truth, therefore, and utility are here the very same
things; 2 and works themselves are of greater value as pledges of
truth than as contributing to the comforts of life. CXXV It may be thought again that I am but doing what has been done before; that
the ancients themselves took the same course which I am now taking; and that it
is likely therefore that I too, after all this stir and striving, shall come at
last to some one of those systems which prevailed in ancient times. For the
ancients, too, it will be said, provided at the outset of their speculations a
great store and abundance of examples and particulars, digested the same into
notebooks under heads and titles, from them completed their systems and arts,
and afterward, when they understood the matter, published them to the world,
adding a few examples here and there for proof and illustration; but thought it
superfluous and inconvenient to publish their notes and minutes and digests of
particulars, and therefore did as builders do: after the house was built they
removed the scaffolding and ladders out of sight. And so no doubt they did. But
this objection (or scruple rather) will be easily answered by anyone who has not
quite forgotten what I have said above. For the form of inquiry and discovery
that was in use among the ancients is by themselves professed and appears on the
very face of their writings. And that form was simply this. From a few examples
and particulars (with the addition of common notions and perhaps of some portion
of the received opinions which have been most popular) they flew at once to the
most general conclusions, or first principles of science. Taking the truth of
these as fixed and immovable, they proceeded by means of intermediate
propositions to educe and prove from them the inferior conclusions; and out of
these they framed the art. After that, if any new particulars and examples
repugnant to their dogmas were mooted and adduced, either they subtly molded
them into their system by distinctions or explanations of their rules, or else
coarsely got rid of them by exceptions; while to such particulars as were not
repugnant they labored to assign causes in conformity with those of their
principles. But this was not the natural history and experience that was wanted;
far from it. And besides, that flying off to the highest generalities ruined
all. 2 Ipsissimæ res. I think this must have been Bacon's
meaning, though not a meaning which the word can properly bear. — J. S. CXXVI It will also be thought that by forbidding men to pronounce and to set down
principles as established until they have duly arrived through the intermediate
steps at the highest generalities, I maintain a sort of suspension of the
judgment, and bring it to what the Greeks call Acatalepsia — a denial of
the capacity of the mind to comprehend truth. But in reality that which I
meditate and propound is not Acatalepsia, but Eucatalepsia; not
denial of the capacity to understand, but provision for understanding truly. For
I do not take away authority from the senses, but supply them with helps; I do
not slight the understanding, but govern it. And better surely it is that we
should know all we need to know, and yet think our knowledge imperfect, than
that we should think our knowledge perfect, and yet not know anything we need to
know. CXXVII It may also be asked (in the way of doubt rather than objection) whether I
speak of natural philosophy only, or whether I mean that the other sciences,
logic, ethics, and politics, should be carried on by this method. Now I
certainly mean what I have said to be understood of them all; and as the common
logic, which governs by the syllogism, extends not only to natural but to all
sciences, so does mine also, which proceeds by induction, embrace everything.
For I form a history and table of discovery for anger, fear, shame, and the
like; for matters political; and again for the mental operations of memory,
composition and division, judgment, and the rest; not less than for heat and
cold, or light, or vegetation, or the like. But, nevertheless, since my method
of interpretation, after the history has been prepared and duly arranged,
regards not the working and discourse of the mind only (as the common logic
does) but the nature of things also, I supply the mind such rules and guidance
that it may in every case apply itself aptly to the nature of things. And
therefore I deliver many and diverse precepts in the doctrine of interpretation,
which in some measure modify the method of invention according to the quality
and condition of the subject of the inquiry. CXXVIII On one point not even a doubt ought to be entertained, namely, whether I
desire to pull down and destroy the philosophy and arts and sciences which are
at present in use. So far from that, I am most glad to see them used,
cultivated, and honored. There is no reason why the arts which are now in
fashion should not continue to supply matter for disputation and ornaments for
discourse, to be employed for the convenience of professors and men of business,
to be, in short, like current coin, which passes among men by consent. Nay, I
frankly declare that what I am introducing will be but little fitted for such
purposes as these, since it cannot be brought down to common apprehension save
by effects and works only. But how sincere I am in my professions of affection
and good will toward the received sciences, my published writings, especially
the books on the advancement of learning, sufficiently show; and therefore I
will not attempt to prove it further by words. Meanwhile I give constant and
distinct warning that by the methods now in use neither can any great progress
be made in the doctrines and contemplative part of sciences, nor can they be
carried out to any magnitude of works. CXXIX It remains for me to say a few words touching the excellency of the end in
view. Had they been uttered earlier, they might have seemed like idle wishes,
but now that hopes have been raised and unfair prejudices removed, they may
perhaps have greater weight. Also if I had finished all myself, and had no
occasion to call in others to help and take part in the work, I should even now
have abstained from such language lest it might be taken as a proclamation of my
own deserts. But since I want to quicken the industry and rouse and kindle the
zeal of others, it is fitting that I put men in mind of some things. In the first place, then, the introduction of famous discoveries appears to
hold by far the first place among human actions; and this was the judgment of
the former ages. For to the authors of inventions they awarded divine honors,
while to those who did good service in the state (such as founders of cities and
empires, legislators, saviors of their country from long endured evils, quellers
of tyrannies, and the like) they decreed no higher honors than heroic. And
certainly if a man rightly compare the two, he will find that this judgment of
antiquity was just. For the benefits of discoveries may extend to the whole race
of man, civil benefits only to particular places; the latter last not beyond a
few ages, the former through all time. Moreover, the reformation of a state in
civil matters is seldom brought in without violence and confusion; but
discoveries carry blessings with them, and confer benefits without causing harm
or sorrow to any. Again, discoveries are as it were new creations, and imitations of God's
works, as the poet well sang: To man's frail race great Athens long ago And it appears worthy of remark in Solomon that, though mighty in empire and
in gold, in the magnificence of his works, his court, his household, and his
fleet, in the luster of his name and the worship of mankind, yet he took none of
these to glory in, but pronounced that "The glory of God is to conceal a thing;
the glory of the king to search it out." Again, let a man only consider what a difference there is between the life of
men in the most civilized province of Europe, and in the wildest and most
barbarous districts of New India; he will feel it be great enough to justify the
saying that "man is a god to man," not only in regard to aid and benefit, but
also by a comparison of condition. And this difference comes not from soil, not
from climate, not from race, but from the arts. Again, it is well to observe the force and virtue and consequences of
discoveries, and these are to be seen nowhere more conspicuously than in those
three which were unknown to the ancients, and of which the origin, though
recent, is obscure and inglorious; namely, printing, gunpowder, and the magnet.
For these three have changed the whole face and state of things throughout the
world; the first in literature, the second in warfare, the third in navigation;
whence have followed innumerable changes, insomuch that no empire, no sect, no
star seems to have exerted greater power and influence in human affairs than
these mechanical discoveries. Further, it will not be amiss to distinguish the three kinds and, as it were,
grades of ambition in mankind. The first is of those who desire to extend their
own power in their native country, a vulgar and degenerate kind. The second is
of those who labor to extend the power and dominion of their country among men.
This certainly has more dignity, though not less covetousness. But if a man
endeavor to establish and extend the power and dominion of the human race itself
over the universe, his ambition (if ambition it can be called) is without doubt
both a more wholesome and a more noble thing than the other two. Now the empire
of man over things depends wholly on the arts and sciences. For we cannot
command nature except by obeying her. Again, if men have thought so much of some one particular discovery as to
regard him as more than man who has been able by some benefit to make the whole
human race his debtor, how much higher a thing to discover that by means of
which all things else shall be discovered with ease! And yet (to speak the whole
truth), as the uses of light are infinite in enabling us to walk, to ply our
arts, to read, to recognize one another — and nevertheless the very beholding of
the light is itself a more excellent and a fairer thing than all the uses of it
— so assuredly the very contemplation of things as they are, without
superstition or imposture, error or confusion, is in itself more worthy than all
the fruit of inventions. Lastly, if the debasement of arts and sciences to purposes of wickedness,
luxury, and the like, be made a ground of objection, let no one be moved
thereby. For the same may be said of all earthly goods: of wit, courage,
strength, beauty, wealth, light itself, and the rest. Only let the human race
recover that right over nature which belongs to it by divine bequest, and let
power be given it; the exercise thereof will be governed by sound reason and
true religion. CXXX And now it is time for me to propound the art itself of interpreting nature,
in which, although I conceive that I have given true and most useful precepts,
yet I do not say either that it is absolutely necessary (as if nothing could be
done without it) or that it is perfect. For I am of the opinion that if men had
ready at hand a just history of nature and experience, and labored diligently
thereon, and if they could bind themselves to two rules — the first, to lay
aside received opinions and notions; and the second, to refrain the mind for a
time from the highest generalizations, and those next to them — they would be
able by the native and genuine force of the mind, without any other art, to fall
into my form of interpretation. For interpretation is the true and natural work
of the mind when freed from impediments. It is true, however, that by my
precepts everything will be in more readiness, and much more sure. Nor again do I mean to say that no improvement can be made upon these. On the
contrary, I regard that the mind, not only in its own faculties, but in its
connection with things, must needs hold that the art of discovery may advance as
discoveries advance. APHORISMS [BOOK TWO] I On a given body, to generate and superinduce a new nature or new natures is
the work and aim of human power. Of a given nature to discover the form, or true
specific difference, or nature-engendering nature, or source of emanation (for
these are the terms which come nearest to a description of the thing), is the
work and aim of human knowledge. Subordinate to these primary works are two
others that are secondary and of inferior mark: to the former, the
transformation of concrete bodies, so far as this is possible; to the latter,
the discovery, in every case of generation and motion, of the latent process
carried on from the manifest efficient and the manifest material to the form
which is engendered; and in like manner the discovery of the latent
configuration of bodies at rest and not in motion. II In what an ill condition human knowledge is at the present time is apparent
even from the commonly received maxims. It is a correct position that "true
knowledge is knowledge by causes." And causes again are not improperly
distributed into four kinds: the material, the formal, the efficient, and the
final. But of these the final cause rather corrupts than advances the sciences,
except such as have to do with human action. The discovery of the formal is
despaired of. The efficient and the material (as they are investigated and
received, that is, as remote causes, without reference to the latent process
leading to the form) are but slight and superficial, and contribute little, if
anything, to true and active science. Nor have I forgotten that in a former
passage I noted and corrected as an error of the human mind the opinion that
forms give existence. For though in nature nothing really exists besides
individual bodies, performing pure individual acts according to a fixed law, yet
in philosophy this very law, and the investigation, discovery, and explanation
of it, is the foundation as well of knowledge as of operation. And it is this
law with its clauses that I mean when I speak of forms, a name which I
the rather adopt because it has grown into use and become familiar. III If a man be acquainted with the cause of any nature (as whiteness or heat) in
certain subjects only, his knowledge is imperfect; and if he be able to
superinduce an effect on certain substances only (of those susceptible of such
effect), his power is in like manner imperfect. Now if a man's knowledge be
confined to the efficient and material causes (which are unstable causes, and
merely vehicles, or causes which convey the form in certain cases) he may arrive
at new discoveries in reference to substances in some degree similar to one
another, and selected beforehand; but he does not touch the deeper boundaries of
things. But whosoever is acquainted with forms embraces the unity of nature in
substances the most unlike, and is able therefore to detect and bring to light
things never yet done, and such as neither the vicissitudes of nature, nor
industry in experimenting, nor accident itself, would ever have brought into
act, and which would never have occurred to the thought of man. From the
discovery of forms therefore results truth in speculation and freedom in
operation. IV Although the roads to human power and to human knowledge lie close together
and are nearly the same, nevertheless, on account of the pernicious and
inveterate habit of dwelling on abstractions it is safer to begin and raise the
sciences from those foundations which have relation to practice, and to let the
active part itself be as the seal which prints and determines the contemplative
counterpart. We must therefore consider, if a man wanted to generate and
superinduce any nature upon a given body, what kind of rule or direction or
guidance he would most wish for, and express the same in the simplest and least
abstruse language. For instance, if a man wishes to superinduce upon silver that
yellow color of gold or an increase of weight (observing the laws of matter), or
transparency on an opaque stone, or tenacity on glass, or vegetation on some
substance that is not vegetable — we must consider, I say, what kind of rule or
guidance he would most desire. And in the first place, he will undoubtedly wish
to be directed to something which will not deceive him in the result nor fail
him in the trial. Secondly, he will wish for such a rule as shall not tie him
down to certain means and particular modes of operation. For perhaps he may not
have those means, nor be able conveniently to procure them. And if there be
other means and other methods for producing the required nature (besides the one
prescribed) these may perhaps be within his reach; and yet he shall be excluded
by the narrowness of the rule, and get no good from them. Thirdly, he will
desire something to be shown him, which is not as difficult as the thing
proposed to be done, but comes nearer to practice. For a true and perfect rule of operation, then, the direction will be that
it be certain, free, and disposing or leading to action. And this is the
same thing with the discovery of the true form. For the form of a nature is
such, that given the form, the nature infallibly follows. Therefore it is always
present when the nature is present, and universally implies it, and is
constantly inherent in it. Again, the form is such that if it be taken away the
nature infallibly vanishes. Therefore it is always absent when the nature is
absent, and implies its absence, and inheres in nothing else. Lastly, the true
form is such that it deduces the given nature from some source of being which is
inherent in more natures, and which is better known in the natural order of
things than the form itself. For a true and perfect axiom of knowledge, then,
the direction and precept will be, that another nature be discovered which is
convertible with the given nature and yet is a limitation of a more general
nature, as of a true and real genus. Now these two directions, the one
active the other contemplative, are one and the same thing; and what in
operation is most useful, that in knowledge is most true. V The rule or axiom for the transformation of bodies is of two kinds. The first
regards a body as a troop or collection of simple natures. In gold, for example,
the following properties meet. It is yellow in color, heavy up to a certain
weight, malleable or ductile to a certain degree of extension; it is not
volatile and loses none of its substance by the action of fire; it turns into a
liquid with a certain degree of fluidity; it is separated and dissolved by
particular means; and so on for the other natures which meet in gold. This kind
of axiom, therefore, deduces the thing from the forms of simple natures. For he
who knows the forms of yellow, weight, ductility, fixity, fluidity, solution,
and so on, and the methods for superinducing them and their gradations and
modes, will make it his care to have them joined together in some body, whence
may follow the transformation of that body into gold. And this kind of operation
pertains to the first kind of action. For the principle of generating some one
simple nature is the same as that of generating many; only that a man is more
fettered and tied down in operation, if more are required, by reason of the
difficulty of combining into one so many natures which do not readily meet,
except in the beaten and ordinary paths of nature. It must be said, however,
that this mode of operation (which looks to simple natures though in a compound
body) proceeds from what in nature is constant and eternal and universal, and
opens broad roads to human power, such as (in the present state of things) human
thought can scarcely comprehend or anticipate. The second kind of axiom, which is concerned with the discovery of the
latent process, proceeds not by simple natures, but by compound bodies, as
they are found in nature in its ordinary course. As, for instance, when inquiry
is made from what beginnings, and by what method and by what process, gold or
any other metal or stone is generated, from its first menstrua and rudiments up
to the perfect mineral; or in like manner, by what process herbs are generated,
from the first concretion of juices in the ground or from seeds up to the formed
plant, with all the successive motions and diverse and continued efforts of
nature. So also in the inquiry concerning the process of development in the
generation of animals, from coition to birth; and in like manner of other
bodies. It is not however only to the generations of bodies that this investigation
extends, but also to other motions and operations of nature. As, for instance,
when inquiry is made concerning the whole course and continued action of
nutrition, from the first reception of the food to its complete assimilation; or
again, concerning the voluntary motion of animals from the first impression on
the imagination and the continued efforts of the spirit up to the bendings and
movements of the limbs; or concerning the motion of the tongue and lips and
other instruments, and the changes through which it passes till it comes to the
utterance of articulate sounds. For these inquiries also relate to natures
concrete or combined into one structure, and have regard to what may be called
particular and special habits of nature, not to her fundamental and universal
laws which constitute forms. And yet it must be confessed that this plan appears
to be readier and to lie nearer at hand and to give more ground for hope than
the primary one. In like manner the operative which answers to this speculative part, starting
from the ordinary incidents of nature, extends its operation to things
immediately adjoining, or at least not far removed. But as for any profound and
radical operations on nature, they depend entirely on the primary axioms. And in
those things too where man has no means of operating, but only of knowing, as in
the heavenly bodies (for these he cannot operate upon or change or transform),
the investigation of the fact itself or truth of the thing, no less than the
knowledge of the causes and consents, must come from those primary and catholic
axioms concerning simple natures, such as the nature of spontaneous rotation, of
attraction or magnetism, and of many others which are of a more general form
than the heavenly bodies themselves. For let no one hope to decide the question
whether it is the earth or heaven that really revolves in the diurnal motion
until he has first comprehended the nature of spontaneous rotation. VI But this latent process of which I speak is quite another thing than men,
preoccupied as their minds now are, will easily conceive. For what I understand
by it is not certain measures or signs or successive steps of process in bodies,
which can be seen; but a process perfectly continuous, which for the most part
escapes the sense. For instance: in all generation and transformation of bodies, we must inquire
what is lost and escapes; what remains, what is added; what is expanded, what
contracted; what is united, what separated; what is continued, what cut off;
what propels, what hinders; what predominates, what yields; and a variety of
other particulars. Again, not only in the generation or transformation of bodies are these
points to be ascertained, but also in all other alterations and motions it
should in like manner be inquired what goes before, what comes after; what is
quicker, what more tardy; what produces, what governs motion; and like points;
all which nevertheless in the present state of the sciences (the texture of
which is as rude as possible and good for nothing) are unknown and unhandled.
For seeing that every natural action depends on things infinitely small, or at
least too small to strike the sense, no one can hope to govern or change nature
until he has duly comprehended and observed them. VII In like manner the investigation and discovery of the latent configuration
in bodies is a new thing, no less than the discovery of the latent process and
of the form. For as yet we are but lingering in the outer courts of nature, nor
are we preparing ourselves a way into her inner chambers. Yet no one can endow a
given body with a new nature, or successfully and aptly transmute it into a new
body, unless he has attained a competent knowledge of the body so to be altered
or transformed. Otherwise he will run into methods which, if not useless, are at
any rate difficult and perverse and unsuitable to the nature of the body on
which he is operating. It is clear therefore that to this also a way must be
opened and laid out. And it is true that upon the anatomy of organized bodies (as of man and
animals) some pains have been well bestowed and with good effect; and a subtle
thing it seems to be, and a good scrutiny of nature. Yet this kind of anatomy is
subject to sight and sense, and has place only in organized bodies. And besides
it is a thing obvious and easy, when compared with the true anatomy of the
latent configuration in bodies which are thought to be of uniform structure,
especially in things and their parts that have a specific character, as iron,
stone; and again in parts of uniform structure in plants and animals, as the
root, the leaf, the flower, flesh, blood, and bones. But even in this kind,
human industry has not been altogether wanting; for this is the very thing aimed
at in the separation of bodies of uniform structure by means of distillations
and other modes of analysis; that the complex structure of the compound may be
made apparent by bringing together its several homogeneous parts. And this is of
use too, and conduces to the object we are seeking, although too often
fallacious in its results, because many natures which are in fact newly brought
out and superinduced by fire and heat and other modes of solution are taken to
be the effect of separation merely, and to have subsisted in the compound
before. And after all, this is but a small part of the work of discovering the
true configuration in the compound body; which configuration is a thing far more
subtle and exact, and such as the operation of fire rather confounds than brings
out and makes distinct. Therefore a separation and solution of bodies must be effected, not by fire
indeed, but by reasoning and true induction, with experiments to aid; and by a
comparison with other bodies, and a reduction to simple natures and their forms,
which meet and mix in the compound. In a word, we must pass from Vulcan to
Minerva if we intend to bring to light the true textures and configurations of
bodies on which all the occult and, as they are called, specific properties and
virtues in things depend, and from which, too, the rule of every powerful
alteration and transformation is derived. For example, we must inquire what amount of spirit there is in every body,
what of tangible essence; and of the spirit, whether it be copious and turgid,
or meager and scarce; whether it be fine or coarse, akin to air or to fire,
brisk or sluggish, weak or strong, progressive or retrograde, interrupted or
continuous, agreeing with external and surrounding objects or disagreeing, etc.
In like manner we must inquire into the tangible essence (which admits of no
fewer differences than the spirit), into its coats, its fibers, its kinds of
texture. Moreover, the disposition of the spirit throughout the corporeal frame,
with its pores, passages, veins and cells, and the rudiments or first essays of
the organized body, falls under the same investigation. But on these inquiries
also, and I may say on all the discovery of the latent configuration, a true and
clear light is shed by the primary axioms which entirely dispels darkness and
subtlety. VIII Nor shall we thus be led to the doctrine of atoms, which implies the
hypothesis of a vacuum and that of the unchangeableness of matter (both false
assumptions); we shall be led only to real particles, such as really exist. Nor
again is there any reason to be alarmed at the subtlety of the investigation, as
if it could not be disentangled. On the contrary, the nearer it approaches to
simple natures, the easier and plainer will everything become, the business
being transferred from the complicated to the simple; from the incommensurable
to the commensurable; from surds to rational quantities; from the infinite and
vague to the finite and certain; as in the case of the letters of the alphabet
and the notes of music. And inquiries into nature have the best result when they
begin with physics and end in mathematics. Again, let no one be afraid of high
numbers or minute fractions. For in dealing with numbers it is as easy to set
down or conceive a thousand as one, or the thousandth part of an integer as an
integer itself. IX From the two kinds of axioms which have been spoken of arises a just division
of philosophy and the sciences, taking the received terms (which come nearest to
express the thing) in a sense agreeable to my own views. Thus, let the
investigation of forms, which are (in the eye of reason at least, and in their
essential law) eternal and immutable, constitute Metaphysics; and let the
investigation of the efficient cause, and of matter, and of the latent process,
and the latent configuration (all of which have reference to the common and
ordinary course of nature, not to her eternal and fundamental laws) constitute
Physics. And to these let there be subordinate two practical divisions:
to Physics, Mechanics; to Metaphysics, what (in a purer sense of the
word) I call Magic, on account of the broadness of the ways it moves in,
and its greater command over nature. X Having thus set up the mark of knowledge, we must go on to precepts, and that
in the most direct and obvious order. Now my directions for the interpretation
of nature embrace two generic divisions: the one how to educe and form axioms
from experience; the other how to deduce and derive new experiments from axioms.
The former again is divided into three ministrations: a ministration to the
sense, a ministration to the memory, and a ministration to the mind or reason. For first of all we must prepare a natural and experimental history,
sufficient and good; and this is the foundation of all, for we are not to
imagine or suppose, but to discover, what nature does or may be made to do. But natural and experimental history is so various and diffuse that it
confounds and distracts the understanding, unless it be ranged and presented to
view in a suitable order. We must therefore form tables and arrangements of
instances, in such a method and order that the understanding may be able to deal
with them. And even when this is done, still the understanding, if left to itself and
its own spontaneous movements, is incompetent and unfit to form axioms, unless
it be directed and guarded. Therefore in the third place we must use induction,
true and legitimate induction, which is the very key of interpretation. But of
this, which is the last, I must speak first, and then go back to the other
ministrations. XI The investigation of forms proceeds thus: a nature being given, we must first
of all have a muster or presentation before the understanding of all known
instances which agree in the same nature, though in substances the most unlike.
And such collection must be made in the manner of a history, without premature
speculation, or any great amount of subtlety. For example, let the investigation
be into the form of heat. Instances Agreeing in the Nature of Heat 1. The rays of the sun, especially in summer and at noon. 2. The rays of the sun reflected and condensed, as between mountains, or on
walls, and most of all in burning glasses and mirrors. 3. Fiery meteors. 4. Burning thunderbolts. 5. Eruptions of flame from the cavities of mountains. 6. All flame. 7. Ignited solids. 8. Natural warm baths. 9. Liquids boiling or heated. 10. Hot vapors and fumes, and the air itself, which conceives the most
powerful and glowing heat if confined, as in reverbatory furnaces. 11. Certain seasons that are fine and cloudless by the constitution of the
air itself, without regard to the time of year. 12. Air confined and underground in some caverns, especially in winter. 13. All villous substances, as wool, skins of animals, and down of birds,
have heat. 14. All bodies, whether solid or liquid, whether dense or rare (as the air
itself is), held for a time near the fire. 15. Sparks struck from flint and steel by strong percussion. 16. All bodies rubbed violently, as stone, wood, cloth, etc., insomuch that
poles and axles of wheels sometimes catch fire; and the way they kindled fire in
the West Indies was by attrition. 17. Green and moist vegetables confined and bruised together, as roses packed
in baskets; insomuch that hay, if damp, when stacked, often catches fire. 18. Quicklime sprinkled with water. 19. Iron, when first dissolved by strong waters in glass, and that without
being put near the fire. And in like manner tin, etc., but not with equal
intensity. 20. Animals, especially and at all times internally; though in insects the
heat is not perceptible to the touch by reason of the smallness of their size. 21. Horse dung and like excrements of animals, when fresh. 22. Strong oil of sulphur and of vitriol has the effect of heat in burning
linen. 23. Oil of marjoram and similar oils have the effect of heat in burning the
bones of the teeth. 24. Strong and well rectified spirit of wine has the effect of heat, insomuch
that the white of an egg being put into it hardens and whitens almost as if it
were boiled, and bread thrown in becomes dry and crusted like toast. 25. Aromatic and hot herbs, as dracunculus, nasturtium vetus, etc.,
although not warm to the hand (either whole or in powder), yet to the tongue and
palate, being a little masticated, they feel hot and burning. 26. Strong vinegar, and all acids, on all parts of the body where there is no
epidermis, as the eye, tongue, or on any part when wounded and laid bare of the
skin, produce a pain but little differing from that which is created by heat. 27. Even keen and intense cold produces a kind of sensation of burning: "Nec
Boreæ penetrabile frigus adurit." 1 28. Other instances. This table I call the Table of Essence and Presence. l Nor burns the sharp cold of the northern blast. XII Secondly, we must make a presentation to the understanding of instances in
which the given nature is wanting; because the form, as stated above, ought no
less to be absent when the given nature is absent, than present when it is
present. But to note all these would be endless. The negatives should therefore be subjoined to the affirmatives, and the
absence of the given nature inquired of in those subjects only that are most
akin to the others in which it is present and forthcoming. This I call the
Table of Deviation, or of Absence in Proximity. Instances in Proximity where the Nature of Heat is Absent Answering to the first affirmative instance. 1. The rays of the moon and of stars and comets are not found to be hot to
the touch; indeed the severest colds are observed to be at the full moons. The larger fixed stars, however, when passed or approached by the sun, are
supposed to increase and give intensity to the heat of the sun, as is the case
when the sun is in the sign Leo, and in the dog days. To the 2nd. 2. The rays of the sun in what is called the middle region of the air do not
give heat; for which there is commonly assigned not a bad reason, viz., that
that region is neither near enough to the body of the sun from which the rays
emanate, nor to the earth from which they are reflected. And this appears from
the fact that on the tops of mountains, unless they are very high, there is
perpetual snow. On the other hand, it has been observed that on the Peak of
Tenerife, and among the Andes of Peru, the very tops of the mountains are free
from snow, which lies only somewhat lower down. Moreover, the air itself at the
very top is found to be by no means cold, but only rare and keen; insomuch that
on the Andes it pricks and hurts the eyes by its excessive keenness, and also
irritates the mouth of the stomach, producing vomiting. And it was observed by
the ancients that on the top of Olympus the rarity of the air was such that
those who ascended it had to carry sponges with them dipped in vinegar and
water, and to apply them from time to time to the mouth and nose, the air being
from its rarity not sufficient to support respiration; and it was further stated
that on this summit the air was so serene, and so free from rain and snow and
wind, that letters traced by the finger in the ashes of the sacrifices on the
altar of Jupiter remained there still the next year without being at all
disturbed. And at this day travelers ascending to the top of the Peak of
Tenerife make the ascent by night and not by day, and soon after the rising of
the sun are warned and urged by their guides to come down without delay, on
account of the danger they run lest the animal spirits should swoon and be
suffocated by the tenuity of the air. To the 2nd. 3. The reflection of the rays of the sun in regions near the polar circles is
found to be very weak and ineffective in producing heat, insomuch that the Dutch
who wintered in Nova Zembla and expected their ship to be freed from the
obstructions of the mass of ice which hemmed her in by the beginning of July,
were disappointed in their expectation and obliged to take to their boat. Thus
the direct rays of the sun seem to have but little power, even on the level
ground; nor have the reflex much, unless they are multiplied and combined, which
is the case when the sun tends more to the perpendicular, for then the incident
rays make acuter angles, so that the lines of the rays are nearer each other;
whereas on the contrary, when the sun shines very obliquely, the angles are very
obtuse, and thus the lines of rays are at a greater distance from each other.
Meanwhile, it should be observed that there may be many operations of the sun,
and those too depending on the nature of heat, which are not proportioned to our
touch, so that in respect to us their action does not go so far as to produce
sensible warmth, but in respect to some other bodies they have the effect of
heat. 4. Try the following experiment. Take a glass fashioned in a contrary manner
to a common burning glass and, placing it between your hand and the rays of the
sun, observe whether it diminishes the heat of the sun, as a burning glass
increases and strengthens it. For it is evident in the case of optical rays that
according as the glass is made thicker or thinner in the middle as compared with
the sides, so do the objects seen through it appear more spread or more
contracted. Observe therefore whether the same is the case with heat. To the 2nd 5. Let the experiment be carefully tried, whether by means of the most
powerful and best constructed burning glasses, the rays of the moon can be so
caught and collected as to produce even the last degree of warmth. But should
this degree of warmth prove too subtle and weak to be perceived and apprehended
by the touch, recourse must be had to those glasses which indicate the state of
the atmosphere in respect to heat and cold. Thus, let the rays of the moon fall
through a burning glass on the top of a glass of this kind, and then observe
whether there ensues a sinking of the water through warmth. To the 2nd. 6. Let a burning glass also be tried with a heat that does not emit rays or
light, as that of iron or stone heated but not ignited, boiling water, and the
like; and observe whether there ensue an increase of the heat, as in the case of
the sun's rays. To the 2nd. 7. Let a burning glass also be tried with common flame. To the 2nd. 8. Comets (if we are to reckon these too among meteors) are not found to
exert a constant or manifest effect in increasing the heat of the season, though
it is observed that they are often followed by droughts. Moreover bright beams
and pillars and openings in the heavens appear more frequently in winter than in
summertime, and chiefly during the intensest cold, but always accompanied by dry
weather. Lightning, however, and coruscations and thunder seldom occur in the
winter, but about the time of great heat. Falling stars, as they are called, are
commonly supposed to consist rather of some bright and lighted viscous
substance, than to be of any strong fiery nature. But on this point let further
inquiry be made. To the 3rd. 9. There are certain coruscations which give light but do not burn. And these
always come without thunder. To the 4th. 10. Eructations and eruptions of flame are found no less in cold than in warm
countries, as in Iceland and Greenland. In cold countries, too, the trees are in
many cases more inflammable and more pitchy and resinous than in warm; as the
fir, pine, and others. The situations however and the nature of the soil in
which eruptions of this kind usually occur have not been carefully enough
ascertained to enable us to subjoin a negative to this affirmative instance. To the 5th. 11. All flame is in all cases more or less warm; nor is there any negative to
be subjoined. And yet they say that the ignis fatuus (as it is called),
which sometimes even settles on a wall, has not much heat, perhaps as much as
the flame of spirit of wine, which is mild and soft. But still milder must that
flame be which, according to certain grave and trustworthy histories has been
seen shining about the head and locks of boys and girls, without at all burning
the hair, but softly playing round it. It is also most certain that about a
horse, when sweating on the road, there is sometimes seen at night, and in clear
weather, a sort of luminous appearance without any manifest heat. And it is a
well-known fact, and looked upon as a sort of miracle, that a few years ago a
girl's stomacher, on being slightly shaken or rubbed, emitted sparks, which was
caused perhaps by some alum or salts used in the dye, that stood somewhat thick
and formed a crust, and were broken by the friction. It is also most certain
that all sugar, whether refined or raw, provided only it be somewhat hard,
sparkles when broken or scraped with a knife in the dark. In like manner sea and
salt water is sometimes found to sparkle by night when struck violently by oars.
And in storms, too, at nighttime, the foam of the sea when violently agitated
emits sparks, and this sparkling the Spaniards call Sea Lung. With regard
to the heat of the flame which was called by ancient sailors Castor and Pollux,
and by moderns St. Elmo's Fire, no sufficient investigation thereof has been
made. To the 6th. 12. Every body ignited so as to turn to a fiery red, even if unaccompanied by
flame, is always hot; neither is there any negative to be subjoined to this
affirmative. But that which comes nearest seems to be rotten wood, which shines
by night and yet is not found to be hot; and the putrefying scales of fish,
which also shine in the dark and yet are not warm to the touch; nor, again, is
the body of the glowworm, or of the fly called Luciola, found to be warm
to the touch. To the 7th. 13. In what situation and kind of soil warm baths usually spring has not been
sufficiently examined; and therefore no negative is subjoined. To the 8th. 14. To warm liquids I subjoin the negative instance of liquid itself in its
natural state. For we find no tangible liquid which is warm in its own nature
and remains so constantly; but the warmth is of an adventitious nature,
superinduced only for the time being, so that the liquids which in power and
operation are hottest, as spirit of wine, chemical oil of spices, oil of vitriol
and sulphur, and the like, which burn after a while, are at first cold to the
touch. The water of natural warm baths, on the other hand, if received into a
vessel and separated from its springs, cools just like water that has been
heated on a fire. But it is true that oily substances are less cold to the touch
than watery, oil being less cold than water, and silk than linen. But this
belongs to the Table of Degrees of Cold. To the 9th. 15. In like manner to hot vapor I subjoin as a negative the nature of vapor
itself, such as we find it with us. For exhalations from oily substances, though
easily inflammable, are yet not found to be warm unless newly exhaled from the
warm body. To the 10th. 16. In like manner I subjoin as a negative to hot air the nature of air
itself. For we do not find here any air that is warm, unless it has either been
confined, or compressed, or manifestly warmed by the sun, fire, or some other
warm substance. To the 11th. 17. I here subjoin the negative of colder weather than is suitable to the
season of the year, which we find occurs during east and north winds; just as we
have weather of the opposite kind with the south and west winds. So a tendency
to rain, especially in wintertime, accompanies warm weather; while frost
accompanies cold. To the 12th. 18. Here I subjoin the negative of air confined in caverns during the summer.
But the subject of air in confinement should by all means be more diligently
examined. For in the first place it may well be a matter of doubt what is the
nature of air in itself with regard to heat and cold. For air manifestly
receives warmth from the influence of the heavenly bodies, and cold perhaps from
the exhalations of the earth; and, again, in the middle region of air, as it is
called, from cold vapors and snow. So that no opinion can be formed as to the
nature of air from the examination of air that is at large and exposed, but a
truer judgment might be made by examining it when confined. It is, however,
necessary for the air to be confined in a vessel of such material as will not
itself communicate warmth or cold to the air by its own nature, nor readily
admit the influence of the outer atmosphere. Let the experiment therefore be
made in an earthen jar wrapped round with many folds of leather to protect it
from the outward air, and let the vessel remain tightly closed for three or four
days; then open the vessel and test the degree of heat or cold by applying
either the hand or a graduated glass. To the 13th. 19. In like manner a doubt suggests itself whether the warmth in wool, skins,
feathers, and the like, proceeds from a faint degree of heat inherent in them,
as being excretions from animals; or from a certain fat and oiliness, which is
of a nature akin to warmth; or simply, as surmised in the preceding article,
from the confinement and separation of the air. For all air that is cut off from
connection with the outer air seems to have some warmth. Try the experiment
therefore with fibrous substances made of linen; not of wool, feathers, or silk,
which are excretions from animals. It should also be observed that all powders
(in which there is manifestly air enclosed) are less cold than the whole
substances they are made from; as likewise I suppose that all froth (as that
which contains air) is less cold than the liquor it comes from. To the 14th. 20. To this no negative is subjoined. For there is nothing found among us,
either tangible or spirituous, which does not contract warmth when put near
fire. There is this difference however, that some substances contract warmth
more quickly, as air, oil, and water; others more slowly, as stone and metal.
But this belongs to the Table of Degrees. To the 15th. 21. To this instance I subjoin no negative, except that I would have it well
observed that sparks are produced from flint and steel, or any other hard
substance, only when certain minute particles are struck off from the substance
of the stone or metal; and that the attrition of the air does not of itself ever
produce sparks, as is commonly supposed. And the sparks themselves, too, owing
to the weight of the ignited body, tend rather downwards than upwards; and on
going out become a tangible sooty substance. To the 16th. 22. There is no negative, I think, to be subjoined to this instance. For we
find among us no tangible body which does not manifestly gain warmth by
attrition; insomuch that the ancients fancied that the heavenly bodies had no
other means or power of producing warmth than by the attrition of the air in
their rapid and hurried revolution. But on this subject we must further inquire
whether bodies discharged from engines, as balls from cannon, do not acquire
some degree of heat from the very percussion, so as to be found somewhat warm
when they fall. Air in motion, however, rather chills than warms, as appears
from wind, bellows, and blowing with the mouth contracted. But motion of this
kind is not so rapid as to excite heat, and is the motion of a mass, and not of
particles; so that it is no wonder if it does not generate heat. To the 17th. 23. On this instance should be made more diligent inquiry. For herbs and
vegetables, when green and moist seem to contain some latent heat, though so
slight that it is not perceptible to the touch when they are single, but only
when they are collected and shut up together, so that their spirits may not
breathe out into the air, but may mutually cherish each other; whereupon there
arises a palpable heat, and sometimes flame in suitable matter. To the 18th. 24. On this instance too should be made more diligent inquiry. For quicklime
sprinkled with water seems to contract heat either by the concentration of heat
before dispersed, as in the above-mentioned case of confined herbs, or because
the igneous spirit is irritated and exasperated by the water so as to cause a
conflict and reaction. Which of these two is the real cause will more readily
appear if oil be poured on instead of water, for oil will serve equally well
with water to concentrate the enclosed spirit, but not to irritate it. We should
also extend the experiment both by employing the ashes and rusts of different
bodies, and by pouring in different liquids. To the 19th. 25. To this instance is subjoined the negative of other metals which are
softer and more fusible. For gold leaf dissolved by aqua regia gives no
heat to the touch; no more does lead dissolved in aqua fortis; neither
again does quicksilver (as I remember); but silver itself does, and copper too
(as I remember); tin still more manifestly; and most of all iron and steel,
which not only excite a strong heat in dissolution but also a violent
ebullition. It appears therefore that the heat is produced by conflict, the
strong waters penetrating, digging into, and tearing asunder the parts of the
substance, while the substance itself resists. But where the substances yield
more easily, there is hardly any heat excited. To the 20th. 26. To the heat of animals no negative is subjoined, except that of insects
(as above-mentioned) on account of their small size. For in fishes, as compared
with land animals, it is rather a low degree than an absence of heat that is
noted. But in vegetables and plants there is no degree of heat perceptible to
the touch, either in their exudations or in their pith when freshly exposed. In
animals, however, is found a great diversity of heat, both in their parts (there
being different degrees of heat about the heart, in the brain, and on the skin)
and in their accidents, as violent exercise and fevers. To the 21st. 27. To this instance it is hard to subjoin a negative. Indeed the excrements
of animals when no longer fresh have manifestly a potential heat, as is seen in
the enriching of soil. To the 24th. 28. Liquids, whether waters or oils, which possess a great and intense
acridity, act like heat in tearing asunder bodies and burning them after some
time; yet to the touch they are not hot at first. But their operation is
relative and according to the porosity of the body to which they are applied.
For aqua regia dissolves gold but not silver; aqua fortis, on the
contrary, dissolves silver, but not gold; neither dissolves glass, and so on
with others. To the 22nd and 23rd. 29. Let trial be made of spirit of wine on wood, and also on butter, wax, or
pitch; and observe whether by its heat it in any degree melts them. For the
twenty-fourth instance exhibits a power in it that resembles heat in producing
incrustation. In like manner therefore try its power in producing liquefaction.
Let trial also be made with a graduated or calendar glass, hollow at the top;
pour into the hollow spirit of wine well rectified, cover it up that the spirit
may better retain its heat, and observe whether by its heat it makes the water
sink. To the 25th. 30. Spices and acrid herbs strike hot on the palate, and much hotter on the
stomach. Observe therefore on what other substances they produce the effects of
heat. Sailors tell us that when large parcels and masses of spices are, after
being long kept close, suddenly opened, those who first stir and take them out
run the risk of fever and inflammation. It can also be tried whether such spices
and herbs when pounded would not dry bacon and meat hung over them, as smoke
does. To the 26th. 31. There is an acridity or pungency both in cold things, as vinegar and oil
of vitriol, and in hot, as oil of marjoram and the like. Both alike therefore
cause pain in animate substances, and tear asunder and consume the parts in such
as are inanimate. To this instance again there is no negative subjoined.
Moreover we find no pain in animals, save with a certain sensation of heat. To the 27th. 32. There are many actions common both to heat and cold, though in a very
different manner. For boys find that snow after a while seems to burn their
hands; and cold preserves meat from putrefaction, no less than fire; and heat
contracts bodies, which cold does also. But these and similar instances may more
conveniently be referred to the inquiry concerning cold. XIII Thirdly, we must make a presentation to the understanding of instances in
which the nature under inquiry is found in different degrees, more or less;
which must be done by making a comparison either of its increase and decrease in
the same subject, or of its amount in different subjects, as compared one with
another. For since the form of a thing is the very thing itself, and the thing
differs from the form no otherwise than as the apparent differs from the real,
or the external from the internal, or the thing in reference to man from the
thing in reference to the universe, it necessarily follows that no nature can be
taken as the true form, unless it always decrease when the nature in question
decreases, and in like manner always increase when the nature in question
increases. This Table therefore I call the Table of Degrees or the
Table of Comparison. Table of Degrees or Comparison in Heat I will therefore first speak of those substances which contain no degree at
all of heat perceptible to the touch, but seem to have a certain potential heat
only, or disposition and preparation for hotness. After that I shall proceed to
substances which are hot actually, and to the touch, and to their intensities
and degrees. 1. In solid and tangible bodies we find nothing which is in its nature
originally hot. For no stone, metal, sulphur, fossil, wood, water, or carcass of
animal is found to be hot. And the hot water in baths seems to be heated by
external causes; whether it be by flame or subterraneous fire, such as is thrown
up from Etna and many other mountains, or by the conflict of bodies, as heat is
caused in the dissolution of iron and tin. There is therefore no degree of heat
palpable to the touch in animate substances; but they differ in degree of cold,
wood not being equally cold with metal. But this belongs to the Table of Degrees
in Cold. 2. As far, however, as potential heat and aptitude for flame is concerned,
there are many inanimate substances found strongly disposed thereto, as sulphur,
naphtha, rock oil. 3. Substances once hot, as horse dung from animal heat, and lime or perhaps
ashes and soot from fire, retain some latent remains of their former heat. Hence
certain distillations and resolutions of bodies are made by burying them in
horse dung, and heat is excited in lime by sprinkling it with water, as already
mentioned. 4. In the vegetable creation we find no plant or part of plant (as gum or
pitch) which is warm to the human touch. But yet, as stated above, green herbs
gain warmth by being shut up; and to the internal touch, as the palate or
stomach, and even to external parts, after a little time, as in plasters and
ointments, some vegetables are perceptibly warm and others cold. 5. In the parts of animals after death or separation from the body, we find
nothing warm to the human touch. Not even horse dung, unless enclosed and
buried, retains its heat. But yet all dung seems to have a potential heat, as is
seen in the fattening of the land. In like manner carcasses of animals have some
such latent and potential heat, insomuch that in burying grounds, where burials
take place daily, the earth collects a certain hidden heat which consumes a body
newly laid in it much more speedily than pure earth. We are told too that in the
East there is discovered a fine soft texture, made of the down of birds, which
by an innate force dissolves and melts butter when lightly wrapped in it. 6. Substances which fatten the soil, as dung of all kinds, chalk, sea sand,
salt, and the like, have some disposition to heat. 7. All putrefaction contains in itself certain elements of a slight heat,
though not so much as to be perceived by the touch. For not even those
substances which on putrefaction turn to animalculae, as flesh, cheese, etc.,
feel warm to the touch; no more does rotten wood, which shines in the dark.
Heat, however, in putrid substances sometimes betrays itself by foul and
powerful odors. 8. The first degree of heat therefore among those substances which feel hot
to the touch, seems to be the heat of animals, which has a pretty great extent
in its degrees. For the lowest, as in insects, is hardly perceptible to the
touch, but the highest scarcely equals the sun's heat in the hottest countries
and seasons, nor is it too great to be borne by the hand. It is said, however,
of Constantius, and some others of a very dry constitution and habit of body,
that in violent fevers they became so hot as somewhat to burn the hand that
touched them. 9. Animals increase in heat by motion and exercise, wine, feasting, venus,
burning fevers, and pain. 10. When attacked by intermittent fevers, animals are at first seized with
cold and shivering, but soon after they become exceedingly hot, which is their
condition from the first in burning and pestilential fevers. 11. Let further inquiry be made into the different degrees of heat in
different animals, as in fishes, quadrupeds, serpents, birds; and also according
to their species, as in the lion, the kite, the man; for in common opinion fish
are the least hot internally, and birds the hottest, especially doves, hawks,
and sparrows. 12. Let further inquiry be made into the different degrees of heat in the
different parts and limbs of the same animal. For milk, blood, seed, eggs, are
found to be hot only in a moderate degree, and less hot than the outer flesh of
the animal when in motion or agitated. But what the degree of heat is in the
brain, stomach, heart, etc., has not yet been in like manner inquired. 13. All animals in winter and cold weather are cold externally, but
internally they are thought to be even hotter. 14. The heat of the heavenly bodies, even in the hottest countries, and at
the hottest times of the year and day, is never sufficiently strong to set on
fire or burn the driest wood or straw, or even tinder, unless strengthened by
burning glasses or mirrors. It is, however, able to extract vapor from moist
substances. 15. By the tradition of astronomers some stars are hotter than others. Of
planets, Mars is accounted the hottest after the sun; then comes Jupiter, and
then Venus. Others, again, are set down as cold: the moon, for instance, and
above all Saturn. Of fixed stars, Sirius is said to be the hottest, then Cor
Leonis or Regulus, then Canicula, and so on. 16. The sun gives greater heat the nearer he approaches to the perpendicular
or zenith; and this is probably true of the other planets also, according to the
proportion of their heat. Jupiter, for instance, is hotter, probably, to us when
under Cancer or Leo than under Capricorn or Aquarius. 17. We must also believe that the sun and other planets give more heat in
perigee, from their proximity to the earth, than they do in apogee. But if it
happens that in some region the sun is at the same time in perigee and near the
perpendicular, his heat must of necessity be greater than in a region where he
is also in perigee, but shining more obliquely. And therefore the altitude of
the planets in their exaltation in different regions ought to be noted, with
respect to perpendicularity or obliquity. 18. The sun and other planets are supposed to give greater heat when nearer
to the larger fixed stars. Thus when the sun is in Leo he is nearer Cor Leonis,
Cauda Leonis, Spica Virginis, Sirius and Canicula, than when he is in Cancer, in
which sign, however, he is nearer to the perpendicular. And it must be supposed
that those parts of the heavens shed the greatest heat (though it be not at all
perceptible to the touch) which are the most adorned with stars, especially of a
larger size. 19. Altogether, the heat of the heavenly bodies is increased in three ways:
first, by perpendicularity; secondly, by proximity or perigee; thirdly, by the
conjunction or combination of stars. 20. The heat of animals, and of the rays of the heavenly bodies also (as they
reach us), is found to differ by a wide interval from flame, though of the
mildest kind, and from all ignited bodies; and from liquids also, and air itself
when highly heated by fire. For the flame of spirit of wine, though scattered
and not condensed, is yet sufficient to set paper, straw, or linen on fire,
which the heat of animals will never do, or of the sun without a burning glass
or mirror. 21. There are, however, many degrees of strength and weakness in the heat of
flame and ignited bodies. But as they have never been diligently inquired into,
we must pass them lightly over. It appears, however, that of all flame that of
spirit of wine is the softest, unless perhaps ignis fatuus be softer, and
the flames or sparklings arising from the sweat of animals. Next to this, as I
suppose, comes flame from light and porous vegetable matter, as straw, reeds,
and dried leaves, from which the flame from hairs or feathers does not much
differ. Next perhaps comes flame from wood, especially such as contains but
little rosin or pitch; with this distinction, however, that the flame from small
pieces of wood (such as are commonly tied up in fagots) is milder than the flame
from trunks and roots of trees. And this you may try any day in furnaces for
smelting iron, in which a fire made with fagots and boughs of trees is of no
great use. After this I think comes flame from oil, tallow, wax, and such like
fat and oily substances, which have no great acrimony. But the most violent heat
is found in pitch and rosin; and yet more in sulphur, camphor, naphtha, rock
oil, and salts (after the crude matter is discharged), and in their compounds,
as gunpowder, Greek fire (commonly called wildfire), and its different kinds,
which have so stubborn a heat that they are not easily extinguished by water. 22. I think also that the flame which results from some imperfect metals is
very strong and eager. But on these points let further inquiry be made. 23. The flame of powerful lightning seems to exceed in strength all the
former, for it has even been known to melt wrought iron into drops, which those
other flames cannot do. 24. In ignited bodies too there are different degrees of heat, though these
again have not yet been diligently examined. The weakest heat of all, I think,
is that from tinder, such as we use to kindle flame with; and in like manner
that of touchwood or tow, which is used in firing cannon. After this comes
ignited wood or coal, and also bricks and the like heated to ignition. But of
all ignited substances, the hottest, as I take it, are ignited metals, as iron,
copper, etc. But these require further investigation. 25. Some ignited bodies are found to be much hotter than some flames. Ignited
iron, for instance, is much hotter and more consuming than flame of spirit of
wine. 26. Of substances also which are not ignited but only heated by fire, as
boiling water and air confined in furnaces, some are found to exceed in heat
many flames and ignited substances. 27. Motion increases heat, as you may see in bellows and by blowing; insomuch
that the harder metals are not dissolved or melted by a dead or quiet fire, till
it be made intense by blowing. 28. Let trial be made with burning glasses, which (as I remember) act thus.
If you place a burning glass at the distance of (say) a span from a combustible
body, it will not burn or consume it so easily as if it were first placed at the
distance of (say) half a span, and then moved gradually and slowly to the
distance of the whole span. And yet the cone and union of rays are the same; but
the motion itself increases the operation of the heat. 29. Fires which break out during a strong wind are thought to make greater
progress against than with it; because the flame recoils more violently when the
wind gives way than it advances while the wind is driving it on. 30. Flame does not burst out, nor is it generated, unless some hollow space
be allowed it to move and play in; except the explosive flame of gunpowder and
the like, where compression and imprisonment increase its fury. 31. An anvil grows very hot under the hammer, insomuch that if it were made
of a thin plate it might, I suppose, with strong and continuous blows of the
hammer, grow red like ignited iron. But let this be tried by experiment. 32. But in ignited substances which are porous, so as to give the fire room
to move, if this motion be checked by strong compression, the fire is
immediately extinguished. For instance, when tinder, or the burning wick of a
candle or lamp, or even live charcoal or coal, is pressed down with an
extinguisher, or with the foot, or any similar instrument, the operation of the
fire instantly ceases. 33. Approximation to a hot body increases heat in proportion to the degree of
approximation. And this is the case also with light; for the nearer an object is
brought to the light, the more visible it becomes. 34. The union of different heats increases heat, unless the hot substances be
mixed together. For a large fire and a small fire in the same room increase one
another's heat; but warm water plunged into boiling water cools it. 35. The continued application of a hot body increases heat, because heat
perpetually passing and emanating from it mingles with the previously existing
heat, and so multiplies the heat. For a fire does not warm a room as well in
half an hour as it does if continued through the whole hour. But this is not the
case with light; for a lamp or candle gives no more light after it has been long
lighted than it did at first. 36. Irritation by surrounding cold increases heat, as you may see in fires
during a sharp frost. And this I think is owing not merely to the confinement
and contraction of the heat, which is a kind of union, but also to irritation.
Thus, when air or a stick is violently compressed or bent, it recoils not merely
to the point it was forced from, but beyond it on the other side. Let trial
therefore be carefully made by putting a stick or some such thing into flame,
and observing whether it is not burnt more quickly at the sides than in the
middle of the flame. 37. There are many degrees in susceptibility of heat. And first of all it is
to be observed how slight and faint a heat changes and somewhat warms even those
bodies which are least of all susceptible of heat. Even the heat of the hand
communicates some heat to a ball of lead or any metal, if held in it a little
while. So readily and so universally is heat transmitted and excited, the body
remaining to all appearance unchanged. 38. Of all substances that we are acquainted with, the one which most readily
receives and loses heat is air; as is best seen in calendar glasses [air
thermoscopes], which are made thus. Take a glass with a hollow belly, a thin and
oblong neck; turn it upside down and lower it, with the mouth downwards and the
belly upwards, into another glass vessel containing water; and let the mouth of
the inserted vessel touch the bottom of the receiving vessel and its neck lean
slightly against the mouth of the other, so that it can stand. And that this may
be done more conveniently, apply a little wax to the mouth of the receiving
glass, but not so as to seal its mouth quite up, in order that the motion, of
which we are going to speak, and which is very facile and delicate, may not be
impeded by want of a supply of air. The lowered glass, before being inserted into the other, must be heated
before a fire in its upper part, that is its belly. Now when it is placed in the
position I have described, the air which was dilated by the heat will, after a
lapse of time sufficient to allow for the extinction of that adventitious heat,
withdraw and contract itself to the same extension or dimension as that of the
surrounding air at the time of the immersion of the glass, and will draw the
water upwards to a corresponding height. To the side of the glass there should
be affixed a strip of paper, narrow and oblong, and marked with as many degrees
as you choose. You will then see, according as the day is warm or cold, that the
air contracts under the action of cold, and expands under the action of heat; as
will be seen by the water rising when the air contracts, and sinking when it
dilates. But the air's sense of heat and cold is so subtle and exquisite as far
to exceed the perception of the human touch, insomuch that a ray of sunshine, or
the heat of the breath, much more the heat of one's hand placed on the top of
the glass, will cause the water immediately to sink in a perceptible degree. And
yet I think that animal spirits have a sense of heat and cold more exquisite
still, were it not that it is impeded and deadened by the grossness of the body. 39. Next to air, I take those bodies to be most sensitive to heat which have
been recently changed and compressed by cold, as snow and ice; for they begin to
dissolve and melt with any gentle heat. Next to them, perhaps, comes
quicksilver. After that follow greasy substances, as oil, butter, and the like;
then comes wood; then water; and lastly stones and metals, which are slow to
heat, especially in the inside. These, however, when once they have acquired
heat retain it very long; in so much that an ignited brick, stone, or piece of
iron, when plunged into a basin of water, will remain for a quarter of an hour,
or thereabouts, so hot that you cannot touch it. 40. The less the mass of a body, the sooner is it heated by the approach of a
hot body; which shows that all heat of which we have experience is in some sort
opposed to tangible matter. 41. Heat, as far as regards the sense and touch of man, is a thing various
and relative; insomuch that tepid water feels hot if the hand be cold, but cold
if the hand be hot. XIV How poor we are in history anyone may see from the foregoing tables, where I
not only insert sometimes mere traditions and reports (though never without a
note of doubtful credit and authority) in place of history proved and instances
certain, but am also frequently forced to use the words "Let trial be made," or
"Let it be further inquired." XV The work and office of these three tables I call the Presentation of
Instances to the Understanding. Which presentation having been made, induction
itself must be set at work; for the problem is, upon a review of the instances,
all and each, to find such a nature as is always present or absent with the
given nature, and always increases and decreases with it; and which is, as I
have said, a particular case of a more general nature. Now if the mind attempt
this affirmatively from the first, as when left to itself it is always wont to
do, the result will be fancies and guesses and notions ill defined, and axioms
that must be mended every day, unless like the schoolmen we have a mind to fight
for what is false; though doubtless these will be better or worse according to
the faculties and strength of the understanding which is at work. To God, truly,
the Giver and Architect of Forms, and it may be to the angels and higher
intelligences, it belongs to have an affirmative knowledge of forms immediately,
and from the first contemplation. But this assuredly is more than man can do, to
whom it is granted only to proceed at first by negatives, and at last to end in
affirmatives after exclusion has been exhausted. XVI We must make, therefore, a complete solution and separation of nature, not
indeed by fire, but by the mind, which is a kind of divine fire. The first work,
therefore, of true induction (as far as regards the discovery of forms) is the
rejection or exclusion of the several natures which are not found in some
instance where the given nature is present, or are found in some instance where
the given nature is absent, or are found to increase in some instance when the
given nature decreases, or to decrease when the given nature increases. Then
indeed after the rejection and exclusion has been duly made, there will remain
at the bottom, all light opinions vanishing into smoke, a form affirmative,
solid, and true and well defined. This is quickly said; but the way to come at
it is winding and intricate. I will endeavor, however, not to overlook any of
the points which may help us toward it. XVII But when I assign so prominent a part to forms, I cannot too often warn and
admonish men against applying what I say to those forms to which their thoughts
and contemplations have hitherto been accustomed. For in the first place I do not at present speak of compound forms, which
are, as I have remarked, combinations of simple natures according to the common
course of the universe: as of the lion, eagle, rose, gold, and the like. It will
be time to treat of these when we come to the latent processes and latent
configurations, and the discovery of them, as they are found in what are called
substances or natures concrete. And even in the case of simple natures I would not be understood to speak of
abstract forms and ideas, either not defined in matter at all, or ill defined.
For when I speak of forms, I mean nothing more than those laws and
determinations of absolute actuality which govern and constitute any simple
nature, as heat, light, weight, in every kind of matter and subject that is
susceptible of them. Thus the form of heat or the form of light is the same
thing as the law of heat or the law of light. Nor indeed do I ever allow myself
to be drawn away from things themselves and the operative part. And therefore
when I say (for instance) in the investigation of the form of heat, "reject
rarity," or "rarity does not belong to the form of heat," it is the same as if I
said, "It is possible to superinduce heat on a dense body"; or, "It is possible
to take away or keep out heat from a rare body." But if anyone conceive that my forms too are of a somewhat abstract nature,
because they mix and combine things heterogeneous (for the heat of heavenly
bodies and the heat of fire seem to be very heterogeneous; so do the fixed red
of the rose or the like, and the apparent red in the rainbow, the opal, or the
diamond; so again do the different kinds of death: death by drowning, by
hanging, by stabbing, by apoplexy, by atrophy; and yet they agree severally in
the nature of heat, redness, death); if anyone, I say, be of this opinion, he
may be assured that his mind is held in captivity by custom, by the gross
appearance of things, and by men's opinions. For it is most certain that these
things, however heterogeneous and alien from each other, agree in the form or
law which governs heat, redness and death; and that the power of man cannot
possibly be emancipated and freed from the common course of nature, and expanded
and exalted to new efficients and new modes of operation, except by the
revelation and discovery of forms of this kind. And yet, when I have spoken of
this union of nature, which is the point of most importance, I shall proceed to
the divisions and veins of nature, as well the ordinary as those that are more
inward and exact, and speak of them in their place. XVIII I must now give an example of the exclusion or rejection of natures which by
the Tables of Presentation are found not to belong to the form of heat;
observing in the meantime that not only each table suffices for the rejection of
any nature, but even any one of the particular instances contained in any of the
tables. For it is manifest from what has been said that any one contradictory
instance overthrows a conjecture as to the form. But nevertheless for clearness'
sake and that the use of the tables may be more plainly shown, I sometimes
double or multiply an exclusion. An Example of Exclusion, or Rejection of Natures from the Form of Heat 1. On account of the rays of the sun, reject the nature of the elements. 2. On account of common fire, and chiefly subterraneous fires (which are the
most remote and most completely separate from the rays of heavenly bodies),
reject the nature of heavenly bodies. 3. On account of the warmth acquired by all kinds of bodies (minerals,
vegetables, skin of animals, water, oil, air, and the rest) by mere approach to
a fire, or other hot body, reject the distinctive or more subtle texture of
bodies. 4. On account of ignited iron and other metals, which communicate heat to
other bodies and yet lose none of their weight or substance, reject the
communication or admixture of the substance of another hot body. 5. On account of boiling water and air, and also on account of metals and
other solids that receive heat but not to ignition or red heat, reject light or
brightness. 6. On account of the rays of the moon and other heavenly bodies, with the
exception of the sun, also reject light and brightness. 7. By a comparison of ignited iron and the flame of spirit of wine (of which
ignited iron has more heat and less brightness, while the flame of spirit of
wine has more brightness and less heat), also reject light and brightness. 8. On account of ignited gold and other metals, which are of the greatest
density as a whole, reject rarity. 9. On account of air, which is found for the most part cold and yet remains
rare, also reject rarity. 10. On account of ignited iron, which does not swell in bulk, but keeps
within the same visible dimensions, reject local or expansive motion of the body
as a whole. 11. On account of the dilation of air in calendar glasses and the like,
wherein the air evidently moves locally and expansively and yet acquires no
manifest increase of heat, also reject local or expansive motion of the body as
a whole. 12. On account of the ease with which all bodies are heated, without any
destruction or observable alteration, reject a destructive nature, or the
violent communication of any new nature. 13. On account of the agreement and conformity of the similar effects which
are wrought by heat and cold, reject motion of the body as a whole, whether
expansive or contractive. 14. On account of heat being kindled by the attrition of bodies, reject a
principial nature. By principial nature I mean that which exists in the nature
of things positively, and not as the effect of any antecedent nature. There are other natures beside these; for these tables are not perfect, but
meant only for examples. All and each of the above-mentioned natures do not belong to the form
of heat. And from all of them man is freed in his operations of heat. XIX In the process of exclusion are laid the foundations of true induction, which
however is not completed till it arrives at an affirmative. Nor is the exclusive
part itself at all complete, nor indeed can it possibly be so at first. For
exclusion is evidently the rejection of simple natures; and if we do not yet
possess sound and true notions of simple natures, how can the process of
exclusion be made accurate? Now some of the above-mentioned notions (as that of
the nature of the elements, of the nature of heavenly bodies, of rarity) are
vague and ill defined. I, therefore, well knowing and nowise forgetting how
great a work I am about (viz., that of rendering the human understanding a match
for things and nature), do not rest satisfied with the precepts I have laid
down, but proceed further to devise and supply more powerful aids for the use of
the understanding; which I shall now subjoin. And assuredly in the
interpretation of nature the mind should by all means be so prepared and
disposed that while it rests and finds footing in due stages and degrees of
certainty, it may remember withal (especially at the beginning) that what it has
before it depends in great measure upon what remains behind. XX And yet since truth will sooner come out from error than from confusion, I
think it expedient that the understanding should have permission, after the
three Tables of First Presentation (such as I have exhibited) have been made and
weighed, to make an essay of the Interpretation of Nature in the affirmative
way, on the strength both of the instances given in the tables, and of any
others it may meet with elsewhere. Which kind of essay I call the Indulgence
of the Understanding, or the Commencement of Interpretation, or the
First Vintage. First Vintage Concerning the Form of Heat It is to be observed that the form of a thing is to be found (as plainly
appears from what has been said) in each and all the instances in which the
thing itself is to be found; otherwise it would not be the form. It follows
therefore that there can be no contradictory instance. At the same time the form
is found much more conspicuous and evident in some instances than in others,
namely in those wherein the nature of the form is less restrained and obstructed
and kept within bounds by other natures. Instances of this kind I call Shining
or Striking Instances. Let us now therefore proceed to the first vintage
concerning the form of heat. From a survey of the instances, all and each, the nature of which heat is a
particular case, appears to be motion. This is displayed most conspicuously in
flame, which is always in motion, and in boiling or simmering liquids, which
also are in perpetual motion. It is also shown in the excitement or increase of
heat caused by motion, as in bellows and blasts; on which see Tab. 3. Inst. 29.;
and again in other kinds of motion, on which see Tab. 3. Inst. 28. and 31. Again
it is shown in the extinction of fire and heat by any strong compression, which
checks and stops the motion; on which see Tab. 3. Inst. 30. and 32. It is shown
also by this, that all bodies are destroyed, or at any rate notably altered, by
all strong and vehement fire and heat; whence it is quite clear that heat causes
a tumult and confusion and violent motion in the internal parts of a body, which
perceptibly tend to its dissolution. When I say of motion that it is as the genus of which heat is a species, I
would be understood to mean not that heat generates motion or that motion
generates heat (though both are true in certain cases), but that heat itself,
its essence and quiddity, is motion and nothing else; limited however by the
specific differences which I will presently subjoin, as soon as I have added a
few cautions for the sake of avoiding ambiguity. Sensible heat is a relative notion, and has relation to man, not to the
universe, and is correctly defined as merely the effect of heat on the animal
spirits. Moreover, in itself it is variable, since the same body, according as
the senses are predisposed, induces a perception of cold as well as of heat.
This is clear from Inst. 41. Tab. 3. Nor again must the communication of heat, or its transitive nature, by means
of which a body becomes hot when a hot body is applied to it, be confounded with
the form of heat. For heat is one thing, heating another. Heat is produced by
the motion of attrition without any preceding heat, an instance which excludes
heating from the form of heat. And even when heat is produced by the approach of
a hot body, this does not proceed from the form of heat, but depends entirely on
a higher and more general nature, viz., on the nature of assimilation or
self-multiplication, a subject which requires a separate inquiry. Again, our notion of fire is popular, and of no use, being made up of the
combination in any body of heat and brightness, as in common flame and bodies
heated to redness. Having thus removed all ambiguity, I come at length to the true specific
differences which limit motion and constitute it the form of heat. The first difference then is this. Heat is an expansive motion whereby a body
strives to dilate and stretch itself to a larger sphere or dimension than it had
previously occupied. This difference is most observable in flame, where the
smoke or thick vapor manifestly dilates and expands itself into flame. It is shown also in all boiling liquid which manifestly swells, rises, and
bubbles, and carries on the process of self-expansion till it turns into a body
far more extended and dilated than the liquid itself, namely, into vapor, smoke,
or air. It appears likewise in all wood and combustibles, from which there generally
arises exudation and always evaporation. It is shown also in the melting of metals which, being of the compactest
texture, do not readily swell and dilate, but yet their spirit being dilated in
itself, and thereupon conceiving an appetite for further dilation, forces and
agitates the grosser parts into a liquid state. And if the heat be greatly
increased it dissolves and turns much of their substance to a volatile state. It is shown also in iron or stones which, though not melted or dissolved, are
yet softened. This is the case also with sticks, which when slightly heated in
hot ashes become flexible. But this kind of motion is best seen in air, which continuously and
manifestly dilates with a slight heat, as appears in Inst. 38. Tab. 3. It is shown also in the opposite nature of cold. For cold contracts all
bodies and makes them shrink, insomuch that in intense frosts nails fall out
from walls, brazen vessels crack, and heated glass, on being suddenly placed in
the cold, cracks and breaks. In like manner air is contracted by a slight chill,
as in Inst. 38. Tab. 3. But on these points I shall speak more at length in the
inquiry concerning Cold. Nor is it surprising that heat and cold should exhibit
many actions in common (for which see Inst. 32. Tab. 2.), when we find two of
the following specific differences (of which I shall speak presently) suiting
nature; though in this specific difference (of which I am now speaking) their
actions are diametrically opposite. For heat gives an expansive and dilating,
cold a contractive and condensing motion. The second difference is a modification of the former, namely, that heat is a
motion expansive or toward the circumference, but with this condition, that the
body has at the same time a motion upward. For there is no doubt that there are
many mixed motions. For instance, an arrow or dart turns as it goes forward, and
goes forward as it turns. And in like manner the motion of heat is at once a
motion of expansion and a motion upward. This difference is shown by putting a
pair of tongs or a poker in the fire. If you put it in perpendicularly and hold
it by the top, it soon burns your hand; if at the side or from below, not nearly
so soon. It is also observable in distillations per descensorium, which men use
for delicate flowers that soon lose their scent. For human industry has
discovered the plan of placing the fire not below but above, that it may burn
the less. For not only flame tends upward, but also all heat. But let trial be made of this in the opposite nature of cold, viz., whether
cold does not contract a body downward as heat dilates a body upward. Take
therefore two iron rods, or two glass tubes, exactly alike; warm them a little
and place a sponge steeped in cold water or snow at the bottom of the one, and
the same at the top of the other. For I think that the extremities of the rod
which has the snow at the top will cool sooner than the extremities of the other
which has the snow at the bottom; just as the opposite is the case with heat. The third specific difference is this: that heat is a motion of expansion,
not uniformly of the whole body together, but in the smaller parts of it; and at
the same time checked, repelled, and beaten back, so that the body acquires a
motion alternative, perpetually quivering, striving and struggling, and
irritated by repercussion, whence springs the fury of fire and heat. This specific difference is most displayed in flame and boiling liquids,
which are perpetually quivering and swelling in small portions, and again
subsiding. It is also shown in those bodies which are so compact that when heated or
ignited they do not swell or expand in bulk, as ignited iron, in which the heat
is very sharp. It is shown also in this, that a fire burns most briskly in the coldest
weather. Again, it is shown in this, that when the air is extended in a calendar glass
without impediment or repulsion — that is to say, uniformly and equably — there
is no perceptible heat. Also when wind escapes from confinement, although it
burst forth with the greatest violence, there is no very great heat perceptible;
because the motion is of the whole, without a motion alternating in the
particles. And with a view to this, let trial be made whether flame does not
burn more sharply toward the sides than in the middle of the flame. It is also shown in this, that all burning acts on minute pores of the body
burnt; so that burning undermines, penetrates, pricks, and stings the body like
the points of an infinite number of needles. It is also an effect of this, that
all strong waters (if suited to the body on which they are acting) act as fire
does, in consequence of their corroding and pungent nature. And this specific difference (of which I am now speaking) is common also to
the nature of cold. For in cold the contractive motion is checked by a resisting
tendency to expand, just as in heat the expansive motion is checked by a
resisting tendency to contract. Thus, whether the particles of a body work
inward or outward, the mode of action is the same though the degree of strength
be very different; because we have not here on the surface of the earth anything
that is intensely cold. See Inst. 27. Tab. [1]. The fourth specific difference is a modification of the last: it is, that the
preceding motion of stimulation or penetration must be somewhat rapid and not
sluggish, and must proceed by particles, minute indeed, yet not the finest of
all, but a degree larger. This difference is shown by a comparison of the effects of fire with the
effects of time or age. Age or time dries, consumes, undermines and reduces to
ashes, no less than fire; indeed, with an action far more subtle; but because
such motion is very sluggish, and acts on particles very small, the heat is not
perceived. It is also shown by comparing the dissolution of iron and gold. Gold is
dissolved without any heat being excited, while the dissolution of iron is
accompanied by a violent heat, though it takes place in about the same time. The
reason is that in gold the separating acid enters gently and works with
subtlety, and the parts of the gold yield easily; whereas in iron the entrance
is rough and with conflict, and the parts of the iron have greater obstinacy. It is shown also to some degree in some gangrenes and mortifications, which
do not excite great heat or pain on account of the subtle nature of
putrefaction. Let this then be the First Vintage or Commencement of Interpretation
concerning the form of heat, made by way of indulgence to the understanding. Now from this our First Vintage it follows that the form or true definition
of heat (heat, that is, in relation to the universe, not simply in relation to
man) is, in few words, as follows: Heat is a motion, expansive, restrained,
and acting in its strife upon the smaller particles of bodies. But the
expansion is thus modified: while it expands all ways, it has at the same
time an inclination upward. And the struggle in the particles is modified
also; it is not sluggish, but hurried and with violence. Viewed with reference to operation it is the same thing. For the direction is
this: If in any natural body you can excite a dilating or expanding motion,
and can so repress this motion and turn it back upon itself that the dilation
shall not proceed equably, but have its way in one part and be counteracted in
another, you will undoubtedly generate heat; without taking into account
whether the body be elementary (as it is called) or subject to celestial
influence; whether it be luminous or opaque; rare or dense; locally expanded or
confined within the bounds of its first dimension; verging to dissolution or
remaining in its original state; animal, vegetable, or mineral, water, oil or
air, or any other substance whatever susceptible of the above-mentioned motion.
Sensible heat is the same thing; only it must be considered with reference to
the sense. Let us now proceed to further aids. XXI The Tables of First Presentation and the Rejection or process of Exclusion
being completed, and also the First Vintage being made thereupon, we are to
proceed to the other helps of the understanding in the Interpretation of Nature
and true and perfect Induction. In propounding which, I mean, when Tables are
necessary, to proceed upon the Instances of Heat and Cold; but when a smaller
number of examples will suffice, I shall proceed at large; so that the inquiry
may be kept clear, and yet more room be left for the exposition of the system. I propose to treat, then, in the first place, of Prerogative Instances;
secondly, of the Supports of Induction; thirdly, of the Rectification
of Induction; fourthly, of Varying the Investigation according to the
nature of the Subject; fifthly, of Prerogative Natures with respect to
Investigation, or of what should be inquired first and what last; sixthly,
of the Limits of Investigation, or a synopsis of all natures in the
universe; seventhly, of the Application to Practice, or of things in
their relation to man; eighthly, of Preparations for Investigation; and
lastly, of the Ascending and Descending Scale of Axioms. XXII Among Prerogative Instances I will place first Solitary Instances.
Those are solitary instances which exhibit the nature under investigation in
subjects which have nothing in common with other subjects except that nature;
or, again, which do not exhibit the nature under investigation in subjects which
resemble other subjects in every respect in not having that nature. For it is
clear that such instances make the way short, and accelerate and strengthen the
process of exclusion, so that a few of them are as good as many. For instance, if we are inquiring into the nature of color, prisms, crystals,
which show colors not only in themselves but externally on a wall, dews, etc.,
are solitary instances. For they have nothing in common with the colors fixed in
flowers, colored stones, metals, woods, etc., except the color. From which we
easily gather that color is nothing more than a modification of the image of
light received upon the object, resulting in the former case from the different
degrees of incidence, in the latter from the various textures and configurations
of the body. These instances are solitary in respect to resemblance. Again, in the same investigation, the distinct veins of white and black in
marble, and the variegation of color in flowers of the same species, are
solitary instances. For the black and white streaks in marble, or the spots of
pink and white in a pink, agree in everything almost except the color. From
which we easily gather that color has little to do with the intrinsic nature of
a body, but simply depends on the coarser and as it were mechanical arrangement
of the parts. These instances are solitary in respect to difference. Both kinds
I call solitary instances, or ferine, to borrow a term from
astronomers. XXIII Among Prerogative Instances I will next place Migratory Instances.
They are those in which the nature in question is in the process of being
produced when it did not previously exist, or on the other hand of disappearing
when it existed before. And therefore, in either transition, such instances are
always twofold, or rather it is one instance in motion or passage, continued
till it reaches the opposite state. Such instances not only accelerate and
strengthen the exclusive process, but also drive the affirmative or form itself
into a narrow compass. For the form of a thing must necessarily be something
which in the course of this migration is communicated, or on the other hand
which in the course of this migration is removed and destroyed. And though every
exclusion promotes the affirmative, yet this is done more decidedly when it
occurs in the same than in different subjects. And the betrayal of the form in a
single instance leads the way (as is evident from all that has been said) to the
discovery of it in all. And the simpler the migration, the more must the
instance be valued. Besides, migratory instances are of great use with a view to
operation, because in exhibiting the form in connection with that which causes
it to be or not to be, they supply a clear direction for practice in some cases;
whence the passage is easy to the cases that lie next. There is, however, in
these instances a danger which requires caution; viz., lest they lead us to
connect the form too much with the efficient, and so possess the understanding,
or at least touch it, with a false opinion concerning the form, drawn from a
view of the efficient/But the efficient is always understood to be merely the
vehicle that carries the form. This is a danger, however, easily remedied by the
process of exclusion legitimately conducted. I must now give an example of a migratory instance. Let the nature to be
investigated be whiteness. An instance migrating to production or existence is
glass whole and pounded. Again, simple water and water agitated into froth. For
glass and water in their simple state are transparent, not white, whereas
pounded glass and water in froth are white, not transparent. We must therefore
inquire what has happened to the glass or water from this migration. For it is
obvious that the form of whiteness is communicated and conveyed by that pounding
of the glass and that agitation of the water. We find, however, that nothing has
been added except the breaking up of the glass and water into small parts, and
the introduction of air. But we have made no slight advance to the discovery of
the form of whiteness when we know that two bodies, both transparent but in a
greater or less degree (viz., air and water, or air and glass), do when mingled
in small portions together exhibit whiteness, through the unequal refraction of
the rays of light. But an example must at the same time be given of the danger and caution to
which I alluded. For at this point it might readily suggest itself to an
understanding led astray by efficient causes of this kind, that air is always
required for the form of whiteness, or that whiteness is generated by
transparent bodies only — notions entirely false, and refuted by numerous
exclusions. Whereas it will be found that (setting air and the like aside)
bodies entirely even in the particles which affect vision are transparent,
bodies simply uneven are white; bodies uneven and in a compound yet regular
texture are all colors except black; while bodies uneven and in a compound,
irregular, and confused texture are black. Here then I have given an example of
an instance migrating to production or existence in the proposed nature of
whiteness. An instance migrating to destruction in the same nature of whiteness
is froth or snow in dissolution. For the water puts off whiteness and puts on
transparency on returning to its integral state without air. Nor must I by any means omit to mention that under migratory instances are to
be included not only those which are passing toward production and destruction,
but also those which are passing toward increase and decrease; since these also
help to discover the form, as is clear from the above definition of form and the
Table of Degrees. The paper, which is white when dry, but when wetted (that is,
when air is excluded and water introduced) is less white and approaches nearer
to the transparent, is analogous to the above given instances. XXIV Among Prerogative Instances I will put in the third place Striking
Instances, of which I have made mention in the First Vintage Concerning
Heat, and which I also call Shining Instances, or Instances Freed and
Predominant. They are those which exhibit the nature in question naked and
standing by itself, and also in its exaltation or highest degree of power; as
being disenthralled and freed from all impediments, or at any rate by virtue of
its strength dominant over, suppressing and coercing them. For since every body
contains in itself many forms of natures united together in a concrete state,
the result is that they severally crush, depress, break, and enthrall one
another, and thus the individual forms are obscured. But certain subjects are
found wherein the required nature appears more in its vigor than in others,
either through the absence of impediments or the predominance of its own virtue.
And instances of this kind strikingly display the form. At the same time in
these instances also we must use caution, and check the hurry of the
understanding. For whatever displays the form too conspicuously and seems to
force it on the notice of the understanding should be held suspect, and recourse
be had to a rigid and careful exclusion. To take an example: let the nature inquired into be heat. A striking instance
of the motion of expansion, which (as stated above) is the main element in the
form of heat, is a calendar glass of air. For flame, though it manifestly
exhibits expansion, still, as susceptible of momentary extinction, does not
display the progress of expansion. Boiling water, too, on account of the easy
transition of water to vapor or air, does not so well exhibit the expansion of
water in its own body. Again, ignited iron and like bodies are so far from
displaying the progress of expansion that in consequence of their spirit being
crushed and broken by the coarse and compact particles which curb and subdue it,
the expansion itself is not at all conspicuous to the senses. But a calendar
glass strikingly displays expansion in air, at once conspicuous, progressive,
permanent, and without transition. To take another example: let the nature inquired into be weight. A striking
instance of weight is quicksilver. For it far surpasses in weight all substances
but gold, and gold itself is not much heavier. But quicksilver is a better
instance for indicating the form of weight than gold, because gold is solid and
consistent, characteristics which seem related to density; whereas quicksilver
is liquid and teeming with spirit, and yet is heavier by many degrees than the
diamond and other bodies that are esteemed the most solid. From which it is
obvious that the form of heaviness or weight depends simply on quantity of
matter and not on compactness of frame. XXV Among Prerogative Instances I will put in the fourth place Clandestine
Instances, which I also call Instances of the Twilight, and which are
pretty nearly the opposites of Striking Instances. For they exhibit the nature
under investigation in its lowest degree of power, and as it were in its cradle
and rudiments; striving indeed and making a sort of first attempt, but buried
under and subdued by a contrary nature. Such instances, however, are of very
great service for the discovery of forms; because as striking instances lead
easily to specific differences, so are clandestine instances the best guides to
genera, that is, to those common natures whereof the natures proposed are
nothing more than particular cases. For example, let the nature proposed be consistency, or the nature of that
which determines its own figure, opposed to which is fluidity. Those are
clandestine instances which exhibit some feeble and low degree of consistency in
a fluid: as a bubble of water, which is a sort of consistent pellicle of
determined figure, made of the body of the water. Of a similar kind are the
droppings from a house, which if there be water to follow, lengthen themselves
out into a very thin thread to preserve the continuity of the water; but if
there be not water enough to follow, then they fall in round drops, which is the
figure that best preserves the water from a solution of continuity. But at the
very moment of time when the thread of water ceases and the descent in drops
begins, the water itself recoils upward to avoid discontinuation. Again in
metals, which in fusion are liquid but more tenacious, the molten drops often
fly to the top and stick there. A somewhat similar instance is that of
children's looking glasses, which little boys make on rushes with spittle, where
also there is seen a consistent pellicle of water. This, however, is much better
shown in that other childish sport when they take water, made a little more
tenacious by soap, and blow it through a hollow reed, and so shape the water
into a sort of castle of bubbles which by the interposition of the air become so
consistent as to admit of being thrown some distance without discontinuation.
But best of all is it seen in frost and snow, which assume such a consistency
that they can be almost cut with a knife, although they are formed out of air
and water, both fluids. All which facts not obscurely intimate that consistent
and fluid are only vulgar notions, and relative to the sense; and that in fact
there is inherent in all bodies a disposition to shun and escape
discontinuation; but that it is faint and feeble in homogeneous bodies (as
fluids), more lively and strong in bodies compounded of heterogeneous matter;
the reason being that the approach of heterogeneous matter binds bodies
together, while the insinuation of homogeneous matter dissolves and relaxes
them. To take another instance, let the proposed nature be the attraction or coming
together of bodies. In the investigation of its form the most remarkable
striking instance is the magnet. But there is a contrary nature to the
attractive; namely, the nonattractive, which exists in a similar substance. Thus
there is iron which does not attract iron, just as lead does not attract lead,
nor wood wood, nor water water. Now a clandestine instance is a magnet armed
with iron, or rather the iron in an armed magnet. For it is a fact in nature
that an armed magnet at some distance off does not attract iron more powerfully
than an unarmed magnet. But if the iron be brought so near as to touch the iron
in the armed magnet, then the armed magnet supports a far greater weight of iron
than a simple and unarmed magnet, on account of the similarity of substance
between the pieces of iron; an operation altogether clandestine and latent in
the iron before the magnet was applied. Hence it is manifest that the form of
coition is something which is lively and strong in the magnet, feeble and latent
in iron. Again, it has been observed that small wooden arrows without an iron
point, discharged from large engines, pierce deeper into wooden material (say
the sides of ships, or the like) than the same arrows tipped with iron, on
account of the similarity of substance between the two pieces of wood; although
this property had previously been latent in the wood. In like manner, although
air does not manifestly attract air or water water in entire bodies, yet a
bubble is more easily dissolved on the approach of another bubble than if that
other bubble were away, by reason of the appetite of coition between water and
water, and between air and air. Such clandestine instances (which, as I have
said, are of the most signal use) exhibit themselves most conspicuously in small
and subtle portions of bodies; the reason being that larger masses follow more
general forms, as shall be shown in the proper place. XXVI Among Prerogative Instances I will put in the fifth place Constitutive
Instances, which I also call Manipular. They are those which
constitute a single species of the proposed nature, a sort of Lesser Form. For
since the genuine forms (which are always convertible with the proposed natures)
lie deep and are hard to find, it is required by the circumstances of the case
and the infirmity of the human understanding that particular forms, which
collect together certain groups of instances (though not all) into some common
notion, be not neglected, but rather be diligently observed. For whatever unites
nature, though imperfectly, paves the way to the discovery of forms. Instances,
therefore, which are useful in this regard are of no despicable power, but have
a certain prerogative. But great caution must here be employed lest the human understanding, after
having discovered many of those particular forms and thereupon established
partitions or divisions of the nature in question, be content to rest therein,
and instead of proceeding to the legitimate discovery of the great form, take it
for granted that the nature from its very roots is manifold and divided, and so
reject and put aside any further union of the nature, as a thing of superfluous
subtlety and verging on mere abstraction. For example, let the proposed nature be memory, or that which excites and
aids the memory. Constitutive instances are: order or distribution, which
clearly aids the memory; also topics or "places" in artificial memory; which may
either be places in the proper sense of the word, as a door, angle,
window, and the like; or familiar and known persons; or any other things at
pleasure (provided they be placed in a certain order), as animals, vegetables;
words, too, letters, characters, historical persons, and the like; although some
of these are more suitable and convenient than others. Such artificial places
help the memory wonderfully, and exalt it far above its natural powers. Again,
verse is learned and remembered more easily than prose. From this group of three
instances, viz., order, artificial places, and verse, one species of aid to the
memory is constituted. And this species may with propriety be called the cutting
off of infinity. For when we try to recollect or call a thing to mind, if we
have no prenotion or perception of what we are seeking, we seek and toil and
wander here and there, as if in infinite space. Whereas, if we have any sure
prenotion, infinity is at once cut off, and the memory has not so far to range.
Now in the three foregoing instances the prenotion is clear and certain. In the
first it must be something which suits the order; in the second it must be an
image which bears some relation or conformity to the places fixed; in the third,
it must be words that fall into the verse; and thus infinity is cut off. Other
instances, again, will give us this second species: that whatever brings the
intellectual conception into contact with the sense (which is indeed the method
most used in mnemonics) assists the memory. Other instances will give us this
third species: that things which make their impression by way of a strong
affection, as by inspiring fear, admiration, shame, delight, assist the memory.
Other instances will give us this fourth species: that things which are chiefly
imprinted when the mind is clear and not occupied with anything else either
before or after, as what is learned in childhood, or what we think of before
going to sleep, also things that happen for the first time, dwell longest in the
memory. Other instances will give us this fifth species: that a multitude of
circumstances or points to take hold of aids the memory; as writing with breaks
and divisions, reading or reciting aloud. Lastly, other instances will give us
this sixth species: that things which are waited for and raise the attention
dwell longer in the memory than what flies quickly by. Thus, if you read
anything over twenty times, you will not learn it by heart so easily as if you
were to read it only ten, trying to repeat it between whiles, and when memory
failed, looking at the book. It appears, then, that there are six lesser forms
of aids to the memory; viz.: the cutting off of infinity; the reduction of the
intellectual to the sensible; impression made on the mind in a state of strong
emotion; impression made on the mind disengaged; multitude of points to take
hold of; expectation beforehand. To take another example, let the proposed nature be taste or tasting. The
following instances are Constitutive. Persons who are by nature without the
sense of smell cannot perceive or distinguish by taste food that is rancid or
putrid, nor food that is seasoned with garlic, or with roses, or the like.
Again, persons whose nostrils are accidentally obstructed by a catarrh cannot
distinguish or perceive anything putrid or rancid or sprinkled with rosewater.
Again, persons thus affected with catarrh, if while they have something fetid or
perfumed in their mouth or palate they blow their nose violently, immediately
perceive the rancidity or the perfume. These instances, then, will give and
constitute this species, or rather division, of taste: that the sense of taste
is in part nothing else than an internal smell, passing and descending from the
upper passages of the nose to the mouth and palate. On the other hand the tastes
of salt, sweet, sour, acid, rough, bitter, and the like, are as perceptible to
those in whom the sense of smell is wanting or stopped as to anyone else; so
that it is clear that the sense of taste is a sort of compound of an internal
smell and a delicate power of touch — of which this is not the place to speak. To take another example, let the proposed nature be the communication of
quality without admixture of substance. The instance of light will give or
constitute one species of communication; heat and the magnet another. For the
communication of light is momentaneous, and ceases at once on the removal of the
original light. But heat and the virtue of the magnet, after they have been
transmitted to or rather excited in a body, lodge and remain there for a
considerable time after the removal of the source of motion. Very great, in short, is the prerogative of constitutive instances; for they
are of much use in the forming of definitions (especially particular
definitions) and in the division and partition of natures; with regard to which
it was not ill said by Plato, "That he is to be held as a god who knows well how
to define and to divide." XXVII Among Prerogative Instances I will put in the sixth place Instances
Conformable, or of Analogy; which I also call Parallels, or
Physical Resemblances. They are those which represent the resemblances and
conjugations of things, not in lesser forms (as constitutive instances do) but
merely in the concrete. Hence they may be called the first and lowest steps
toward the union of nature. Nor do they constitute any axiom immediately from
the beginning, but simply point out and mark a certain agreement in bodies. But
although they are of little use for the discovery of forms, they nevertheless
are very serviceable in revealing the fabric of the parts of the universe, and
anatomizing its members; from which they often lead us along to sublime and
noble axioms, especially those which relate to the configuration of the world
rather than to simple forms and natures. For example, these following are instances of conformity: a looking glass and
the eye; and again, the construction of the ear and places returning an echo.
From which conformity, to say nothing of the mere observation of the resemblance
which is in many respects useful, it is easy to gather and form this axiom —
that the organs of the senses, and bodies which produce reflections to the
senses, are of a like nature. Again, upon this hint the understanding easily
rises to a higher and nobler axiom, which is this: that there is no difference
between the consents or sympathies of bodies endowed with sensation and those of
inanimate bodies without sensation, except that in the former an animal spirit
is added to the body so disposed, but is wanting in the latter. Whence it
follows that there might be as many senses in animals as there are sympathies
between inanimate bodies, if there were perforations in the animate body
allowing the animal spirit to pass freely into a member rightly disposed, as
into a fit organ. Again, as many as are the senses in animals, so many without
doubt are the motions in an inanimate body where animal spirit is wanting;
though necessarily there are many more motions in inanimate bodies than there
are senses in animate, on account of the paucity of organs of sense. And of this
a manifest example is exhibited in pain. For though there are many kinds and
varieties of pain in animals (as the pain of burning, for one, of intense cold
for another; again, of pricking, squeezing, stretching, and the like), it is yet
most certain that all of them, as far as the motion is concerned, exist in
inanimate substances; for example, in wood or stone, when it is burned or frozen
or pricked or cut or bent or stretched, and so on, though they do not enter the
senses for want of the animal spirit. Again, the roots and branches of plants (which may seem strange) are
conformable instances. For all vegetable matter swells and pushes out its parts
to the surface, as well upward as downward. Nor is there any other difference
between roots and branches than that the root is buried in the ground, while the
branches are exposed to the air and sun. For if you take a tender and
flourishing branch of a tree, and bend it down into a clod of earth, although it
does not cohere with the ground itself, it presently produces not a branch but a
root. And vice versa, if earth be placed at the top, and so kept down with a
stone or any hard substance as to check the plant and prevent it from shooting
upward, it will put forth branches into the air downward. Again, the gums of trees, and most rock gems, are conformable instances. For
both of these are nothing else than exudations and filterings of juices, the
former from trees, the latter from rocks; whence is produced the splendor and
clearness in each, that is, by the fine and delicate filtering. Hence, too, it
is that the hairs of animals are not generally so beautiful and of so vivid a
color as the feathers of birds, viz., because the juices do not filter so finely
through skin as through quills. Again, the scrotum in males and the matrix in females are conformable
instances. So that the great organic difference between the sexes (in land
animals at least) appears to be nothing more than that the one organization is
external and the other internal. That is to say, the greater force of heat in
the male thrusts the genitals outward; whereas in the female the heat is too
feeble to effect this, and thus they are contained within. The fins of fish, again, and the feet of quadrupeds, or the feet and wings of
birds, are conformable instances; to which Aristotle has added the four folds in
the motions of serpents. Whence it appears that in the structure of the universe
the motions of living creatures are generally effected by a quaternion of limbs
or of bendings. Again, the teeth of land animals and the beaks of birds are conformable
instances; from which it is manifest that in all perfect animals there is a
determination of some hard substance to the mouth. Nor is that an absurd similitude of conformity which has been remarked
between man and a plant inverted. For the root of the nerves and faculties in
animals is the head, while the seminal parts are the lowest — the extremities of
the legs and arms not reckoned. In a plant, on the other hand, the root (which
answers to the head) is regularly placed in the lowest part, and the seeds in
the highest. To conclude, it cannot too often be recommended and enjoined that men's
diligence in investigating and amassing natural history be henceforward entirely
changed and turned into the direction opposite to that now in use. For hitherto
men have used great and indeed overcurious diligence in observing the variety of
things, and explaining the exact specific differences of animals, herbs, and
fossils; most of which are rather sports of nature than of any serious use
toward science. Such things indeed serve to delight, and sometimes even give
help in practice; but for getting insight into nature they are of little service
or none. Men's labor therefore should be turned to the investigation and
observation of the resemblances and analogies of things, as well in wholes as in
parts. For these it is that detect the unity of nature, and lay a foundation for
the constitution of sciences. But here must be added a strict and earnest caution, that those only are to
be taken for conformable and analogous instances which indicate (as I said at
the beginning) physical resemblances, that is, real and substantial
resemblances; resemblances grounded in nature, not accidental or merely
apparent; much less superstitious or curious resemblances, such as the writers
on natural magic (very frivolous persons, hardly to be named in connection with
such serious matters as we are now about) are everywhere parading — similitudes
and sympathies of things that have no reality, which they describe and sometimes
invent with great vanity and folly. But to leave these. The very configuration of the world itself in its greater
parts presents conformable instances which are not to be neglected. Take, for
example, Africa and the region of Peru with the continent stretching to the
Straits of Magellan, in each of which tracts there are similar isthmuses and
similar promontories, which can hardly be by accident. Again, there is the Old and New World, both of which are broad and extended
towards the north, narrow and pointed towards the south. We have also most remarkable instances of conformity in the intense cold
existing in what is called the middle region of the air and the violent fires
which are often found bursting forth from beneath the ground, which two things
are ultimities and extremes; that is to say, the extreme of the nature of
cold toward the circumference of the sky, of heat toward the bowels of the
earth, by antiperistasis or the rejection of the contrary nature. Lastly, the conformity of instances in the axioms of science is deserving of
notice. Thus the rhetorical trope of deceiving expectation is conformable with
the musical trope of avoiding or sliding from the close or cadence; the
mathematical postulate that if two things are equal to the same thing they are
equal to one another is conformable with the rule of the syllogism in logic
which unites propositions agreeing in a middle term. In fine, a certain sagacity
in investigating and hunting out physical conformities and similitudes is of
very great use in very many cases. XXVIII Among Prerogative Instances I will put in the seventh place Singular
Instances, which I also call Irregular or Heteroclite, to
borrow a term from grammarians. They are such as exhibit bodies in the concrete,
which seem to be out of the course and broken off from the order of nature, and
not agreeing with other bodies of the same kind. For conformable instances are
like each other; singular instances are like themselves alone. The use of
singular instances is the same as that of clandestine, namely, to raise and
unite nature for the purpose of discovering kinds of common natures, to be
afterward limited by true specific differences. For we are not to give up the
investigation until the properties and qualities found in such things as may be
taken for miracles of nature be reduced and comprehended under some form or
fixed law, so that all the irregularity or singularity shall be found to depend
on some common form, and the miracle shall turn out to be only in the exact
specific differences, and the degree, and the rare concurrence, not in the
species itself. Whereas now the thoughts of men go no further than to pronounce
such things the secrets and mighty works of nature, things as it were causeless,
and exceptions to general rules. Examples of singular instances are the sun and moon among stars; the magnet
among stones; quicksilver among metals; the elephant among quadrupeds; the
venereal sense among kinds of touch; the scent of hounds among kinds of smell.
So among grammarians the letter S is held singular, on account of its easy
combination with consonants, sometimes with two, sometimes even with three,
which property no other letter has. Such instances must be regarded as most
valuable, because they sharpen and quicken investigation and help to cure the
understanding depraved by custom and the common course of things. XXIX Among Prerogative Instances I will put in the eighth place Deviating
Instances, that is, errors, vagaries, and prodigies of nature, wherein
nature deviates and turns aside from her ordinary course. Errors of nature
differ from singular instances in this, that the latter are prodigies of
species, the former of individuals. Their use is pretty nearly the same, for
they correct the erroneous impressions suggested to the understanding by
ordinary phenomena, and reveal common forms. For in these also we are not to
desist from inquiry until the cause of the deviation is discovered. This cause,
however, does not rise properly to any form, but simply to the latent process
that leads to the form. For he that knows the ways of nature will more easily
observe her deviations; and on the other hand he that knows her deviations will
more accurately describe her ways. They differ in this also from singular instances, that they give much more
help to practice and the operative part. For to produce new species would be
very difficult, but to vary known species and thereby produce many rare and
unusual results is less difficult. Now it is an easy passage from miracles of
nature to miracles of art. For if nature be once detected in her deviation, and
the reason thereof made evident, there will be little difficulty in leading her
back by art to the point whither she strayed by accident; and that not only in
one case, but also in others. For errors on one side point out and open the way
to errors and deflections on all sides. Under this head there is no need of
examples, they are so plentiful. For we have to make a collection or particular
natural history of all prodigies and monstrous births of nature; of everything
in short that is in nature new, rare, and unusual. This must be done, however,
with the strictest scrutiny, that fidelity may be ensured. Now those things are
to be chiefly suspected which depend in any way on religion, as the prodigies of
Livy, and those not less which are found in writers on natural magic or alchemy,
and men of that sort, who are a kind of suitors and lovers of fables. But
whatever is admitted must be drawn from grave and credible history and
trustworthy reports. XXX Among Prerogative Instances I will put in the ninth place Bordering
Instances, which I also call Participles. They are those which
exhibit species of bodies that seem to be composed of two species, or to be
rudiments between one species and another. These instances might with propriety
be reckoned among singular or heteroclite instances, for in the whole extent of
nature they are of rare and extraordinary occurrence. But nevertheless for their
worth's sake they should be ranked and treated separately, for they are of
excellent use in indicating the composition and structure of things, and
suggesting the causes of the number and quality of the ordinary species in the
universe, and carrying on the understanding from that which is to that which may
be. Examples of these are: moss, which holds a place between putrescence and a
plant; some comets, between stars and fiery meteors; flying fish, between birds
and fish; bats, between birds and quadrupeds; also the ape, between man and
beast — Simia quam similis turpissima bestia nobis; likewise the biformed births of animals, mixed of different species, and the
like. XXXI Among Prerogative Instances I will put in the tenth place Instances of
Power, or of the Fasces (to borrow a term from the badges of empire);
which I also call Instances of the Wit, or Hands of Man. These are
the noblest and most consummate works in each art, exhibiting the ultimate
perfection of it. For since our main object is to make nature serve the business
and conveniences of man, it is altogether agreeable to that object that the
works which are already in man's power should (like so many provinces formerly
occupied and subdued) be noted and enumerated, especially such as are the most
complete and perfect; because starting from them we shall find an easier and
nearer passage to new works hitherto unattempted. For if from an attentive
contemplation of these a man pushes on his work with zeal and activity, he will
infallibly either advance them a little further, or turn them aside to something
in their neighborhood, or even apply and transfer them to some more noble use. Nor is this all. But as by rare and extraordinary works of nature the
understanding is excited and raised to the investigation and discovery of forms
capable of including them, so also is this done by excellent and wonderful works
of art, and that in a much greater degree, because the method of creating and
constructing such miracles of art is in most cases plain, whereas in the
miracles of nature it is generally obscure. But with these also we must use the
utmost caution lest they depress the understanding and fasten it as it were to
the ground. For there is danger lest the contemplation of such works of art, which appear
to be the very* summits and crowning points of human industry, may so astonish
and bind and bewitch the understanding with regard to them, that it shall be
incapable of dealing with any other, but shall think that nothing can be done in
that kind except by the same way in which these were done — only with the use of
greater diligence and more accurate preparation. Whereas on the contrary this is certain: that the ways and means of achieving
the effects and works hitherto discovered and observed are for the most part
very poor things, and that all power of a high order depends on forms and is
derived in order from the sources thereof; not one of which has yet been
discovered. And therefore (as I have said elsewhere) if a man had been thinking of the
war engines and battering-rams of the ancients, though he had done it with all
his might and spent his whole life in it, yet he would never have lighted on the
discovery of cannon acting by means of gunpowder. Nor again, if he had fixed his
observation and thought on the manufacture of wool and cotton, would he ever by
such means have discovered the nature of the silkworm or of silk. Hence it is that all the discoveries which can take rank among the nobler of
their kind have (if you observe) been brought to light, not by small
elaborations and extensions of arts, but entirely by accident. Now there is
nothing which can forestall or anticipate accident (which commonly acts only at
long intervals) except the discovery of forms. Particular examples of such instances it is unnecessary to adduce, for there
is such an abundance of them. For what we have to do is simply this: to seek out
and thoroughly inspect all mechanical arts, and all liberal too (as far as they
deal with works), and make therefrom a collection or particular history of the
great and masterly and most perfect works in every one of them, together with
the mode of their production or operation. And yet I do not tie down the diligence that should be used in such a
collection to those works only which are esteemed the masterpieces and mysteries
of any art, and which excite wonder. For wonder is the child of rarity; and if a
thing be rare, though in kind it be no way extraordinary, yet it is wondered at.
While on the other hand things which really call for wonder on account of the
difference in species which they exhibit as compared with other species, yet if
we have them by us in common use, are but slightly noticed. Now the singularities of art deserve to be noticed no less than those of
nature, of which I have already spoken. And as among the singularities of nature
I placed the sun, the moon, the magnet, and the like — things in fact most
familiar, but in nature almost unique — so also must we do with the
singularities of art. For example, a singular instance of art is paper, a thing exceedingly common.
Now if you observe them with attention, you will find that artificial materials
are either woven in upright and transverse threads, as silk, woolen or linen
cloth, and the like; or cemented of concreted juices, as brick, earthenware,
glass, enamel, porcelain, etc., which are bright if well united, but if not, are
hard indeed but not bright. But all things that are made of concrete juices are
brittle, and no way cohesive or tenacious. On the contrary, paper is a tenacious
substance that may be cut or torn; so that it imitates and almost rivals the
skin or membrane of an animal, the leaf of a vegetable, and the like pieces of
nature's workmanship. For it is neither brittle like glass, nor woven as cloth;
but is in fibers, not distinct threads, just like natural materials; so that
among artificial materials you will hardly find anything similar; but it is
altogether singular. And certainly among things artificial those are to be
preferred which either come nearest to an imitation of nature, or on the
contrary overrule and turn her back. Again, as instances of the wit and hand of man, we must not altogether
contemn juggling and conjuring tricks. For some of them, though in use trivial
and ludicrous, yet in regard to the information they give may be of much value. Lastly, matters of superstition and magic (in the common acceptation of the
word) must not be entirely omitted. For although such things lie buried deep
beneath a mass of falsehood and fable, yet they should be looked into a little.
For it may be that in some of them some natural operation lies at the bottom, as
in fascination, strengthening of the imagination, sympathy of things at a
distance, transmission of impressions from spirit to spirit no less than from
body to body, and the like. XXXII From what has been said it is clear that the five classes of instances last
mentioned (namely, Instances Conformable, Singular, Deviating, Bordering, and of
Power) ought not to be reserved until some certain nature be in question (as the
other instances which I have placed first, and most of those that are to follow
should), but a collection of them must be begun at once, as a sort of particular
history; because they serve to digest the matters that enter the understanding,
and to correct the ill complexion of the understanding itself, which cannot but
be tinged and infected, and at length perverted and distorted, by daily and
habitual impression. These instances therefore should be employed as a sort of preparative for
setting right and purging the understanding. For whatever withdraws the
understanding from the things to which it is accustomed, smooths and levels its
surface for the reception of the dry and pure light of true ideas. Moreover such instances pave and prepare the way for the operative part, as
will be shown in the proper place, when I come to speak of deductions leading to
Practice. XXXIII Among Prerogative Instances I will put in the eleventh place Instances of
Companionship and of Enmity, which I also call Instances of Fixed
Propositions. They are those which exhibit a body or concrete substance in
which the nature inquired into constantly attends, as an inseparable companion;
or in which on the contrary it constantly retreats, and is excluded from
companionship as an enemy and foe. For from such instances are formed certain
and universal propositions, either affirmative or negative, in which the subject
will be a body in concrete, and the predicate the nature itself that is in
question. For particular propositions are in no case fixed. I mean propositions
in which the nature in question is found in any concrete body to be fleeting and
movable, that is to say accruing or acquired, or on the other hand departing or
put away. Wherefore particular propositions have no prerogative above others,
save only in the case of migration, of which I have already spoken. Nevertheless
even these particular propositions being prepared and collated with universal
propositions are of great use, as shall be shown in the proper place. Nor even
in the universal propositions do we require exact or absolute affirmation or
negation. For it is sufficient for the purpose in hand even if they admit of
some rare and singular exception. The use of instances of companionship is to bring the affirmative of the form
within narrow limits. For if by migratory instances the affirmative of the form
is narrowed to this, that the form of the thing must needs be something which by
the act of migration is communicated or destroyed; so in instances of
companionship, the affirmative of the form is narrowed to this, that the form of
the thing must needs be something which enters as an element into such a
concretion of body, or contrariwise which refuses to enter; so that he who well
knows the constitution or configuration of such a body will not be far from
bringing to light the form of the nature under inquiry. For example, let the nature in question be heat. An instance of companionship
is flame. For in water, air, stone, metal, and most other substances, heat is
variable, and may come and go, but all flame is hot, so that heat is always in
attendance on the concretion of flame. But no hostile instance of heat is to be
found here. For the senses know nothing of the bowels of the earth, and of all
the bodies which we do know there is not a single concretion that is not
susceptible to heat. But to take another instance: let the nature in question be consistency. A
hostile instance is air. For metal can be fluid and can also be consistent; and
so can glass; water also can be consistent, when it is frozen; but it is
impossible that air should ever be consistent, or put off its fluidity. But with regard to such instances of fixed propositions I have two
admonitions to give, which may help the business in hand. The first is that, if
a universal affirmative or negative be wanting, that very thing be carefully
noted as a thing that is not; as we have done in the case of heat, where a
universal negative (as far as the essences that have come under our knowledge
are concerned) is not to be found in the nature of things. In like manner, if
the nature in question be eternity or incorruptibility, no universal affirmative
is to be found here. For eternity or incorruptibility cannot be predicated of
any of the bodies lying below the heavens and above the bowels of the earth. The
other admonition is that to universal propositions, affirmative or negative,
concerning any concrete body, there be subjoined those concretes which seem to
approach most nearly to that which is not; as in heat, the gentlest and least
burning flames; in incorruptibility, gold which comes nearest to it. For all
such indicate the limits of nature between that which is and that which is not,
and help to circumscribe forms and prevent them from escaping and straying
beyond the conditions of matter. XXXIV Among Prerogative Instances I will put in the twelfth place those
Subjunctive Instances mentioned in the last aphorism, which I otherwise call
Instances of Ultimity or Limit. For such instances are not only useful
when subjoined to fixed propositions, but also by themselves and in their own
properties. For they point out not obscurely the real divisions of nature and
measures of things, and how far in any case nature may act or be acted upon, and
then the passages of nature into something else. Of this kind are gold in
weight; iron in hardness; the whale in animal bulk; the dog in scent; the
combustion of gunpowder in rapid expansion; and the like. Nor should extremes in
the lowest degree be less noticed than extremes in the highest; such as spirit
of wine in weight; silk in softness; the worms of the skin in animal bulk; and
the like. XXXV Among Prerogative Instances I will put in the thirteenth place Instances
of Alliance or Union. They are those which mingle and unite natures supposed
to be heterogeneous, and marked and set down as such in the received divisions. Instances of alliance show that operations and effects attributed to some one
heterogeneous nature as peculiar to it may belong also to other heterogeneous
natures; that this supposed heterogeneity is proved to be not real or essential,
but only a modification of a common nature. They are therefore of most excellent
use in raising and elevating the understanding from specific differences to
genera, and in dispelling phantoms and false images of things, which in
concrete substances come before us in disguise. For example, let the nature in
question be heat. We are told (and it seems to be a division quite received and
authorized) that there are three kinds of heat: the heat of heavenly bodies, the
heat of animals, and the heat of fire; and that these heats (especially one of
them as compared with the other two) are in their very essence and species —
that is to say, in their specific nature — distinct and heterogeneous, since the
heat of heavenly bodies and of animals generates and cherishes, while the heat
of fire wastes and destroys. We have, therefore, an instance of alliance in that
common case, when the branch of a vine is brought within a house where a fire is
constantly kept up, and the grapes ripen on it a whole month sooner than they do
out of doors; so that the ripening of fruit, even while it hangs on the tree,
may be brought about by fire, though such ripening would seem to be the proper
work of the sun. From this beginning, therefore, the understanding, rejecting
the notion of essential heterogeneity, easily rises to inquire what are in
reality those points of difference between the heat of the sun and of fire which
cause their operations to be so dissimilar, however they may themselves partake
of a common nature. These differences will be found to be four. The first is that the heat of the
sun compared with the heat of fire is far milder and softer in degree; the
second is that in quality (at least as it reaches us through the air) it is far
moister; the third (and this is the main point) is that it is exceedingly
unequal, now approaching and increased, now receding and diminished; which thing
chiefly contributes to the generation of bodies. For Aristotle was right in
asserting that the principal cause of the generations and corruptions which are
going on here on the surface of the earth is the oblique course of the sun
through the zodiac; whence the heat of the sun, partly by the alternation of day
and night, partly by the succession of summer and winter, becomes strangely
unequal. And yet this great man must go on at once to corrupt and deprave what
he has rightly discovered. For laying down the law to nature (as his way is), he
very dictatorially assigns as the cause of generation the approach of the sun,
and as the cause of corruption his retreat; whereas both together (the approach
of the sun and his retreat), not respectively, but as it were indifferently,
afford a cause both for generation and production; since inequality of heat
ministers to generation and corruption, equality to conservation only. There is
also a fourth specific difference between the heat of the sun and of fire, and
one of very great moment; viz., that the sun operates by gentle action through
long spaces of time, whereas the operations of fire, urged on by the impatience
of man, are made to finish their work in shorter periods. But if anyone were to
set to work diligently to temper the heat of fire and reduce it to a milder and
more moderate degree, as is easily done in many ways, and were then to sprinkle
and intermix a little moisture; and if above all he were to imitate the heat of
the sun in its inequality; and lastly if he could submit to a slow procedure,
not indeed corresponding to the operations of the sun, but yet slower than men
generally adopt in working with fire; he would speedily get rid of the notion of
different kinds of heat, and would attempt to imitate, if not equal or in some
cases even surpass the works of the sun by the heat of fire. We have a similar
instance of alliance in the revival of butterflies stupefied and half dead with
cold, by slightly warming them at a fire. So that you may easily see that fire
is no more without the power of giving life to animals than of ripening
vegetables. Thus also Fracastorius' celebrated invention of the heated pan with
which doctors cover the heads of apoplectic patients who are given over,
manifestly expands the animal spirits, compressed and all but extinguished by
the humors and obstructions of the brain, and exciting them to motion, just as
fire acts on air or water, by consequence quickens and gives them life. Eggs
also are sometimes hatched by the heat of fire, which thus exactly imitates
animal heat. And there are many instances of the same kind, so that no one can
doubt that the heat of fire may in many subjects be modified so as to resemble
the heat of heavenly bodies and of animals. Again, let the natures in question be motion and rest. It appears to be a
received division and drawn from the depths of philosophy, that natural bodies
either move in circle, or move straight forward, or remain at rest. For there is
either motion without limit, or rest at a limit, or progress toward a limit.
Now, that perpetual motion of rotation seems to be proper to the heavenly
bodies, station or rest seems to belong to the globe of the earth, while other
bodies (which they call heavy or light, being indeed placed out of the region to
which they naturally belong) are carried toward the masses or congregations of
their likes; light bodies upward toward the circumference of the heaven, heavy
bodies downward towards the earth. And this is pretty talk. But we have an instance of alliance in one of the lower comets, which though
far below the heaven, nevertheless revolve. And Aristotle's fiction of a comet
being tied to or following some particular star has long been exploded, not only
because the reason for it is not probable, but because we have manifest
experience of the discursive and irregular motion of comets through various
parts of the sky. Again, another instance of alliance on this subject is the motion of air,
which within the tropics, where the circles of rotation are larger, seems itself
also to revolve from east to west. Again, another instance would be the ebb and flow of the sea, if it be found
that the waters themselves are carried in a motion of rotation (however slow and
evanescent) from east to west, though subject to the condition of being driven
back twice in the day. For if things be so, it is manifest that that motion of
rotation is not limited to heavenly bodies, but is shared also by air and water. Even that property of light substances, viz., that they tend upward, is
somewhat at fault. And on this point a bubble of water may be taken as an
instance of alliance. For if there be air under the water it rapidly ascends to
the surface by that motion of percussion (as Democritus calls it) by which the
descending water strikes and raises the air upward; not by any effort or
struggle of the air itself. And when it is come to the surface of the water,
then the air is stopped from further ascent by a slight resistance it meets with
in the water, which does not immediately allow itself to be separated; so that
the desire of air to ascend must be very slight. Again, let the nature in question be weight. It is quite a received division
that dense and solid bodies move toward the center of the earth, rare and light
toward the circumference of the heaven, as to their proper places. Now as for
this notion of places, though such things prevail in the schools, it is very
silly and childish to suppose that place has any power. Therefore philosophers
do but trifle when they say that if the earth were bored through, heavy bodies
would stop on reaching the center. Certainly it would be a wonderful and
efficacious sort of nothing, or mathematical point, which could act on bodies,
or for which bodies could have desire, for bodies are not acted on except by
bodies. But this desire of ascending and descending depends either on the
configuration of the body moved or on its sympathy or consent with some other
body. Now if there be found any body which, being dense and solid, does not move
to the earth, there is an end of this division. But if Gilbert's opinion be received, that the earth's magnetic power of attracting
heavy bodies does not extend beyond the orb of its virtue (which acts always to
a certain distance and no more), and if this opinion be verified by a single
instance, in that we shall have got at last an instance of alliance on the
subject of weight. But at present there does not occur any instance on this
subject certain and manifest. What seems to come nearest to one is that of the
waterspouts, often seen in the voyage over the Atlantic Ocean toward either of
the Indies. For so great is the quantity and mass of water suddenly discharged
by these waterspouts that they seem to have been collections of water made
before, and to have remained hanging in these places, and afterward to have been
rather thrown down by some violent cause, than to have fallen by the natural
motion of gravity. So that it may be conjectured that a dense and compact mass,
at a great distance from the earth, would hang like the earth itself and not
fall unless thrust down. But on this point I affirm nothing certain. Meanwhile
in this and many other cases it will easily be seen how poor we are in natural
history, when in place of certain instances I am sometimes compelled to adduce
as examples bare suppositions. Again, let the nature in question be discourse of reason. The distinction
between human reason and the sagacity of brutes appears to be a perfectly
correct one. Yet there are certain instances of actions performed by animals, by
which it seems that brutes too have some power of syllogizing; as in the old
story of the crow which, in a time of great drought being half dead with thirst,
saw some water in the hollow trunk of a tree, and finding it too narrow to get
in, proceeded to drop in a number of pebbles till the water rose high enough for
it to drink; and this afterward passed into a proverb. Again, let the nature in question be visibility. It appears to be a very
correct and safe division which regards light as primarily visible, and
affording the power of seeing; while color is secondarily visible, and cannot be
seen without light, so that it appears to be nothing more than an image or
modification of light. And yet there appear to be instances of alliance on
either side, namely, snow in great quantities, and the flame of sulphur; in one
of which there appears to be a color primarily giving light, in the other a
light verging on color. XXXVI Among Prerogative Instances I will put in the fourteenth place Instances
of the Fingerpost, borrowing the term from the fingerposts which are set up
where roads part, to indicate the several directions. These I also call
Decisive and Judicial, and in some cases, Oracular and Commanding
Instances. I explain them thus. When in the investigation of any nature the
understanding is so balanced as to be uncertain to which of two or more natures
the cause of the nature in question should be assigned on account of the
frequent and ordinary concurrence of many natures, instances of the fingerpost
show the union of one of the natures with the nature in question to be sure and
indissoluble, of the other to be varied and separable; and thus the question is
decided, and the former nature is admitted as the cause, while the latter is
dismissed and rejected. Such instances afford very great light and are of high
authority, the course of interpretation sometimes ending in them and being
completed. Sometimes these instances of the fingerpost meet us accidentally
among those already noticed, but for the most part they are new, and are
expressly and designedly sought for and applied, and discovered only by earnest
and active diligence. For example, let the nature in question be the ebb and flow of the sea; each
of which is repeated twice a day, and takes six hours each time, subject to some
slight difference which coincides with the motion of the moon. The following
will be a case of the parting of the roads. This motion must necessarily be caused either by the advance and retreat of
the waters, as water shaken in a basin leaves one side when it washes the other;
or else by a lifting up of the waters from the bottom and falling again, as
water in boiling rises and falls. The question is to which of these two causes
the ebb and flow should be assigned. Now, if we take the first, it follows that
when there is a flood on one side of the sea, there must be at the same time an
ebb somewhere on the other. To this point therefore the inquiry is brought. Now
it has been observed by Acosta and others, after careful research, that on the
shores of Florida and the opposite shores of Spain and Africa the floods take
place at the same times, and the ebbs take place at the same times also; and not
that there is an ebb from the shores of Spain and Africa when there is a flood
on the shores of Florida. And yet if you look at it more closely, this does not
prove the case in favor of the rising and against the progressive motion. For
waters may move in progression, and yet rise upon the opposite shores of the
same channel at the same time, as when they are thrust together and driven on
from some other quarter. For so it is with rivers, which rise and fall on both
banks at the same hours. And yet that motion is clearly one of progression,
namely, of the waters entering the mouth of the rivers from the sea. It may
therefore happen in a like manner that waters coming in a vast mass from the
East Indian Ocean are driven together and pushed into the channel of the
Atlantic, and on that account flood both sides at once. We must inquire
therefore whether there be any other channel in which the water can be
retreating and ebbing at that same time; and we have the South Sea, a sea at
least as wide, indeed wider and larger than the Atlantic, which is sufficient
for the purpose. At length then, we have come to an instance of the fingerpost in this case,
and it is this. If we find for certain that when there is a flood on the
opposite coasts of Florida and Spain in the Atlantic, there is also a flood on
the coasts of Peru and the back of China in the South Sea, then indeed on the
authority of this decisive instance we must reject the assertion that the ebb
and flow of the sea, which is the thing inquired into, takes place by a
progressive motion; for there is no sea or place left in which the retreat or
ebbing can be going on at the same time. And this may be most conveniently
ascertained by asking the inhabitants of Panama and Lima (where the two oceans,
the Atlantic and Pacific, are separated by a small isthmus) whether the ebb and
flow of the sea takes place on the opposite sides of the isthmus at the same
time; or contrariwise, when it is ebbing on one side it is flowing on the other.
Now this decision or rejection appears to be certain, if we take it for granted
that the earth is immovable. But if the earth revolves, it is perhaps possible
that in consequence of the unequal rotation (in point of speed) of the earth and
waters of the sea, the waters are violently driven upwards into a heap, which is
the flood, and (when they can bear no more piling) released and let down again,
which is the ebb. But on this inquiry should be made separately. Still, even on
this hypothesis, our position remains equally fixed, that there must of
necessity be an ebb of the sea going on in some parts at the same time that a
flood is going on in others. Again, let the nature in question be the latter of the two motions we have
supposed, namely, the rising and sinking motion, if on careful examination we
reject the former motion of which I spoke — the progressive. With regard to this
nature the road branches into three. For the motion by which the waters rise in
the flood and sink in the ebb without any accession of other waters rolling in,
must necessarily be brought about in one of these three ways. Either there is an
accession of water poured out from the interior of the earth, and again
retreating into it; or there is no accession to the mass of water, but the same
waters (without increase of quantity) are extended or rarefied so as to occupy a
greater space and dimension, and again contract themselves; or there is no
increase either of supply or of extension, but the same waters (the same in
quantity as in density) are raised by some magnetic force attracting them from
above, and by consent therewith, and then fall back again. Let us now dismiss
the two former causes of motion and reduce our inquiry to the last; that is to
say, let us inquire whether any such raising by consent or magnetic force may
happen. Now in the first place it is evident that the waters, as they lie in the
trench or hollow of the sea, cannot all be raised at once for want of something
to take their place at the bottom; so that even if there were in water any such
desire to rise, it would be barred and checked by the cohesion of things, or (as
it is commonly called) the abhorrence of a vacuum. It remains that the waters
must be raised in one part, and thereby be diminished and retreat in another.
Again, it will follow of necessity that the magnetic force, since it cannot act
upon the whole, will act with the greatest intensity on the middle, so as to
raise up the water in the middle; upon which the rest must follow and fall away
from the sides. Thus at length we come to an instance of the fingerpost on this subject. For
if we find that in the ebb of the sea the surface of the water is more arched
and round, the waters rising in the middle of the sea and falling away from the
sides, that is, the shores; and that in the flood the same surface is more even
and level, the waters returning to their former position; then indeed on the
authority of this decisive instance the raising by magnetic force may be
admitted; otherwise it must be utterly rejected. And this would not be difficult
to ascertain by trial in straits with sounding lines, viz., whether during ebbs
the sea be not higher or deeper toward the middle than during floods. It is to
be observed however that, if this be the case, the waters must (contrary to the
common opinion) rise in ebbs and sink in floods, so as to clothe and wash the
shores. Again, let the nature investigated be the spontaneous motion of rotation, and
in particular whether the diurnal motion whereby to our eyes the sun and stars
rise and set, be a real motion of rotation in the heavenly bodies, or a motion
apparent in the heavenly bodies, and real in the earth. We may here take for an
instance of the fingerpost the following. If there be found in the ocean any
motion from east to west, however weak and languid; if the same motion be found
a little quicker in the air, especially within the tropics, where because of the
larger circles it is more perceptible; if the same motion be found in the lower
comets, but now lively and vigorous; if the same motion be found in planets, but
so distributed and graduated that the nearer a planet is to the earth its motion
is slower, the further a planet is distant from the earth its motion is quicker,
and quickest of all in the starry sphere; then indeed we should receive the
diurnal motion as real in the heavens, and deny such motion to the earth.
Because it will be manifest that motion from east to west is perfectly cosmical,
and by consent of the universe, being most rapid in the highest parts of the
heavens, and gradually falling off, and finally stopping and becoming extinct in
the immovable — that is, the earth. Again, let the nature in question be that other motion of rotation so much
talked of by philosophers, the resistant and contrary motion to the diurnal,
viz., from west to east, which old philosophers attribute to the planets, also
to the starry sphere, but Copernicus and his followers to the earth as well. And
let us inquire whether any such motion be found in nature, or whether it be not
rather a thing invented and supposed for the abbreviation and convenience of
calculation, and for the sake of that pretty notion of explaining celestial
motions by perfect circles. For this motion in the heavens is by no means proved
to be true and real, either by the failing of a planet to return in its diurnal
motion to the same point of the starry sphere, or by this, that the poles of the
zodiac differ from the poles of the world; to which two things we owe this idea
of motion. For the first phenomenon is well accounted for by supposing that the
fixed stars outrun the planets and leave them behind; the second, by supposing a
motion in spiral lines; so that the inequality of return and the declination to
the tropics may rather be modifications of the one diurnal motion than motions
contrary or round different poles. And most certain it is, if one may but play
the plain man for a moment (dismissing the fancies of astronomers and schoolmen,
whose way it is to overrule the senses, often without reason, and to prefer what
is obscure), that this motion does actually appear to the sense such as I have
described; for I once had a machine made with iron wires to represent it. The following would be an instance of the fingerpost on this subject. If it
be found in any history worthy of credit that there has been any comet, whether
high or low, which has not revolved in manifest agreement (however irregular)
with the diurnal motion, but has revolved in the opposite direction, then
certainly we may set down thus much as established, that there may be in
nature some such motion. But if nothing of the kind can be found, it must be
regarded as questionable, and recourse be had to other instances of the
fingerpost about it. Again, let the nature in question be weight or heaviness. Here the road will
branch into two, thus. It must needs be that heavy and weighty bodies either
tend of their own nature to the center of the earth, by reason of their proper
configuration; or else that they are attracted by the mass and body of earth
itself as by the congregation of kindred substances, and move to it by sympathy.
If the latter of these be the cause, it follows that the nearer heavy bodies
approach to the earth, the more rapid and violent is their motion to it; and
that the further they are from the earth, the feebler and more tardy is their
motion (as is the case with magnetic attraction); and that this action is
confined to certain limits. So that if they were removed to such a distance from
the earth that the earth's virtue could not act upon them, they would remain
suspended like the earth itself, and not fall at all. With regard to this, then,
the following would be an instance of the fingerpost. Take a clock moved by
leaden weights, and another moved by the compression of an iron spring. Let them
be exactly adjusted, that one go not faster or slower than the other. Then place
the clock moving by weights on the top of a very high steeple, keeping the other
down below, and observe carefully whether the clock on the steeple goes more
slowly than it did on account of the diminished virtue of its weights. Repeat
the experiment in the bottom of a mine, sunk to a great depth below the ground;
that is, observe whether the clock so placed does not go faster than it did on
account of the increased virtue of its weights. If the virtue of the weights is
found to be diminished on the steeple and increased in the mine, we may take the
attraction of the mass of the earth as the cause of weight. Again, let the nature investigated be the polarity of the iron needle when
touched with the magnet. With regard to this nature the road will branch into
two, thus. Either the touch of the magnet of itself invests the iron with
polarity to the north and south; or it simply excites and prepares the iron,
while the actual motion is communicated by the presence of the earth, as Gilbert
thinks, and labors so strenuously to prove. To this point therefore tend the
observations which he has collected with great sagacity and industry. One is,
that an iron nail which has lain for a long time in a direction between north
and south gathers polarity without the touch of the magnet by its long
continuance in this position; as if the earth itself, which on account of the
distance acts but feebly (the surface or outer crust of the earth being
destitute, as he insists, of magnetic power), were yet able by this long
continuance to supply the touch of the magnet and excite the iron, and then
shape and turn it when excited. Another is, that if iron that has been heated
white-hot be, while cooling, laid lengthwise between north and south, it also
acquires polarity without the touch of the magnet; as if the parts of the iron,
set in motion by ignition and afterwards recovering themselves, were at the very
moment of cooling more susceptible and sensitive to the virtue emanating from
the earth than at other times, and thus became excited by it. But these things,
though well observed, do not quite prove what he asserts. Now with regard to this question an instance of the fingerpost would be the
following. Take a magnetic globe and mark its poles; and set the poles of the
globe toward the east and west, not toward the north and south, and let them
remain so. Then place at the top an untouched iron needle, and allow it to
remain in this position for six or seven days. The needle while over the magnet (for on this point there is no dispute) will
leave the poles of the earth and turn toward the poles of the magnet; and
therefore, as long as it remains thus, it points east and west. Now if it be
found that the needle, on being removed from the magnet and placed on a pivot,
either starts off at once to the north and south, or gradually turns in that
direction, then the presence of the earth must be admitted as the cause; but if
it either points as before east and west, or loses its polarity, this cause must
be regarded as questionable, and further inquiry must be made. Again, let the nature in question be the corporeal substance of the moon;
that is, let us inquire whether it be rare, consisting of flame or air, as most
of the old philosophers opined, or dense and solid, as Gilbert and many moderns,
with some ancients, maintain. The reasons for the latter opinion rest chiefly on
this, that the moon reflects the rays of the sun; nor does light seem to be
reflected except by solid bodies. Therefore instances of the fingerpost on this
question will (if any) be those which prove that reflection may take place from
a rare body, as flame, provided it be of sufficient denseness. Certainly, one
cause of twilight, among others, is the reflection of the rays of the sun from
the upper part of the air. Likewise we occasionally see rays of the sun in fine
evenings reflected from the fringes of dewy clouds with a splendor not inferior
to that reflected from the body of the moon, but brighter and more gorgeous; and
yet there is no proof that these clouds have coalesced into a dense body of
water. Also we observe that the dark air behind a window at night reflects the
light of a candle, just as a dense body would. We should also try the experiment
of allowing the sun's rays to shine through a hole on some dusky bluish flame.
For indeed the open rays of the sun, falling on the duller kinds of flame,
appear to deaden them so that they seem more like white smoke than flame. These
are what occur to me at present as instances of the fingerpost with reference to
this question, and better may perhaps be found. But it should always be observed
that reflection from flame is not to be expected, except from a flame of some
depth, for otherwise it borders on transparency. This however may be set down as
certain — that light on an even body is always either received and transmitted
or reflected. Again, let the nature in question be the motion of projectiles (darts,
arrows, balls, etc.) through the air. This motion the schoolmen, as their way
is, explain in a very careless manner, thinking it enough to call it a violent
motion as distinguished from what they call a natural motion; and to account for
the first percussion or impulse by the axiom that two bodies cannot occupy the
same place on account of the impenetrability of matter, and not troubling
themselves at all how the motion proceeds afterward. But with reference to this
inquiry the road branches into two in this way. Either this motion is caused by
the air carrying the projected body and collecting behind it, as the stream in
the case of a boat, or the wind in that of straws; or it is caused by the parts
of the body itself not enduring the impression, but pushing forward in
succession to relieve themselves from it. The former of these explanations is
adopted by Fracastorius and almost all who have entered into the investigation
with any subtlety, and there is no doubt that the air has something to do
with it. But the other notion is undoubtedly the true one, as is shown by
countless experiments. Among others the following would be an instance of the
fingerpost on this subject: that a thin iron plate or stiffish iron wire, or
even a reed or pen split in half, when pressed into a curve between the finger
and thumb, leaps away. For it is obvious that this motion cannot be imputed to
the air gathering behind the body, because the source of motion is in the middle
of the plate or reed, not in the extremities. Again, let the nature in question be the rapid and powerful motion of the
expansion of gunpowder into flame, by which such vast masses are upheaved, such
great weights discharged, as we see in mines and mortars. With respect to this
nature the road branches into two in this way. The motion is excited either by
the mere desire of the body to expand when set on fire, or partly by that and
partly by the desire of the crude spirit in the body, which flies rapidly away
from the fire and bursts violently from its embrace as from a prison house. The
schoolmen and common opinion deal only with the former desire. For men fancy
themselves very fine philosophers when they assert that the flame is endowed by
its elementary form with a necessity of occupying a larger space than the body
had filled when in the form of powder, and that hence the motion ensues.
Meanwhile, they forget to notice that although this be true on the supposition
that flame is generated, it is yet possible for the generation of flame to be
hindered by a mass of matter sufficient to suppress and choke it; so that the
case is not reduced to the necessity they insist on. For that expansion must
necessarily take place, and that there must needs follow thereon a discharge or
removal of the opposing body, if flame be generated, they rightly judge. But
this necessity is altogether avoided if the solid mass suppress the flame before
it be generated. And we see that flame, especially in its first generation, is
soft and gentle, and requires a hollow space wherein to play and try its
strength. Such violence therefore cannot be attributed to flame by itself. But
the fact is that the generation of these windy flames, or fiery winds as they
may be called, arises from a conflict of two bodies of exactly opposite natures;
the one being highly inflammable, which is the nature of sulphur, the other
abhorring flame, as the crude spirit in niter. So that there ensues a strange
conflict, the sulphur kindling into flame with all its might (for the third
body, the willow charcoal, does no more than incorporate and combine the other
two), while the spirit of the niter bursts forth with all its might and at the
same time dilates itself (as air, water, and all crude bodies do when affected
by heat), and by thus flying and bursting out fans meanwhile the flame of the
sulphur on all sides as with hidden bellows. On this subject we may have instances of the fingerpost of two kinds. The
first, of those bodies which are most highly inflammable, as sulphur, camphor,
naphtha and the like, with their compounds, which catch fire more quickly and
easily than gunpowder if not impeded (from which it appears that the desire of
bursting into flame does not produce by itself that stupendous effect); the
other, of those bodies which shun and abhor flame, as all salts. For we find
that if salts are thrown into the fire their aqueous spirit bursts out with a
crackling noise before flame is caught; which is the case also, though in a
milder degree, with the stiffer kinds of leaves, the aqueous part escaping
before the oily catches fire. But this is best seen in quicksilver, which is not
inaptly called mineral water. For quicksilver, without bursting into flame, by
mere eruption and expansion almost equals the force of gunpowder, and is also
said, when mixed with gunpowder, to increase its strength. Again, let the nature in question be the transitory nature of flame and its
instantaneous extinction. For the nature of flame appears to have no fixed
consistency here with us, to be every moment generated and every moment
extinguished; for it is clear that in flames which continue and last, the
continuance we see is not of the same individual flame, but is caused by a
succession of new flame regularly generated. Nor does the flame remain
numerically identical, as is easily seen from this, that if the food or fuel of
flame be taken away, the flame instantly goes out. With reference to this nature
the roads branch into two, thus: the instantaneous nature proceeds either from a
cessation of the cause which at first produced the flame, as in light, sound,
and the motion called "violent"; or from this, that the flame, though able by
its own nature to remain with us, suffers violence and is destroyed by the
contrary natures that surround it. On this subject therefore we may take the following as an instance of the
fingerpost. We see in large fires how high the flames ascend, for the broader
the base of the flame, the higher is its vertex. Thus extinction appears to
commence at the sides, where the flame is compressed and troubled by the air.
But the heart of the flame, which is not touched by the air but surrounded by
other flame on all sides, remains numerically identical; nor is it extinguished
until gradually compressed by the surrounding air. Thus all flame is in the form
of a pyramid, being broader at the base where the fuel is, but sharp at the
vertex, where the air is antagonistic and fuel is wanting. But smoke is narrow
at the base and grows broader as it ascends, like an inverted pyramid; the
reason being that the air admits smoke and compresses flame. For let no one
dream that lighted flame is air, when in fact they are substances quite
heterogeneous. But we may have an instance of the fingerpost more nicely adapted to this
purpose, if the thing can be made manifest with bicolored lights. Fix a lighted
wax taper in a small metal stand; place the stand in the middle of a bowl, and
pour round it spirit of wine, but not enough to reach the top of the stand. Then
set fire to the spirit of wine. The spirit of wine will yield a bluish, the
taper a yellow flame. Observe therefore whether the flame of the taper (which is
easily distinguished by its color from the flame of the spirit of wine, since
flames do not mix at once, as liquids do) remains in a conical or rather tends
to a globular form, now that there is nothing to destroy or compress it. If the
latter is found to be the case, it may be set down as certain that flame remains
numerically identical as long as it is enclosed within other flame and feels not
the antagonistic action of the air. Let this suffice for instances of the fingerpost. I have dwelt on them at
some length to the end that men may gradually learn and accustom themselves to
judge of nature by instances of the fingerpost and experiments of light, and not
by probable reasonings. XXXVII Among Prerogative Instances I will put in the fifteenth place Instances of
Divorce, which indicate the separation of natures of most familiar
occurrence. They differ from the instances subjoined to the instances of
companionship, in that the latter indicate the separation of a nature from some
concrete substance with which it is ordinarily in conjunction, while these
instances indicate the separation of one nature from another. They differ from
instances of the fingerpost, in that they determine nothing, but simply notify
the separability of one nature from another. Their use is to detect false forms
and to dissipate slight theories suggested by what lies on the surface, and so
serve as ballast to the understanding. For example, let the natures investigated be those four natures which
Telesius accounts as messmates and chamber fellows, namely: heat, brightness,
rarity, mobility or promptness to motion. We find, however, many instances of
divorce between them. For air is rare and mobile, not hot or bright; the moon is
bright without heat; boiling water is hot without light; the motion of an iron
needle on a pivot is quick and nimble, and yet the body is cold, dense, and
opaque; and there are many more of the kind. Again, let the natures investigated be corporeal nature and natural action.
For it seems that natural action is not found except as subsisting in some body.
Yet in this case also we shall perhaps be able to find some instance of divorce;
such, for example, as magnetic action, by which iron is drawn to the magnet,
heavy bodies to the globe of the earth. There may also be added some other
operations performed at a distance. For such action takes place both in time,
occupying moments not a mere instant of time, and in space, passing through
degrees and distances. There is therefore some moment of time, and some distance
of space, in which the virtue or action remains suspended between the two bodies
which produce the motion. The question therefore is brought to this: whether the
bodies which are the limits of the motion dispose or alter the intermediate
bodies, so that by a succession of actual contacts the virtue passes from limit
to limit, meanwhile subsisting in the intermediate body; or whether there is no
such thing, but only the bodies, the virtue, and the distances. In rays of
light, indeed, and sounds, and heat, and certain other things acting at a
distance, it is probable that the intermediate bodies are disposed and altered,
the more so because they require a medium qualified for carrying on the
operation. But that magnetic or attractive virtue admits of media without
distinction, nor is the virtue impeded in any kind of medium. And if the virtue
or action has nothing to do with the intermediate body, it follows that there is
a natural virtue or action subsisting for a certain time and in a certain space
without a body, since it neither subsists in the limiting nor in the
intermediate bodies. And therefore magnetic action may be an instance of divorce
between corporeal nature and natural action. To which may be appended as a
corollary or advantage not to be omitted that here is a proof furnished by
merely human philosophy of the existence of essences and substances separate
from matter and incorporeal. For allow that natural virtue and action, emanating
from a body, can exist for a certain time and in a certain space altogether
without a body, and you are not far from allowing that it can also emanate
originally from an incorporeal substance. For corporeal nature appears to be no
less requisite for sustaining and conveying natural action than for exciting or
generating it. XXXVIII Now follow five classes of instances which under one general name I call
Instances of the Lamp, or of First Information. They are those which
aid the senses. For since all interpretation of nature commences with the senses
and leads from the perceptions of the senses by a straight, regular, and guarded
path to the perceptions of the understanding, which are true notions and axioms,
it follows of necessity that the more copious and exact the representations of
the senses, the more easily and prosperously will everything proceed. Of these five instances of the lamp, the first strengthen, enlarge, and
rectify the immediate actions of the senses; the second make manifest things
which are not directly perceptible by means of others which are; the third
indicate the continued processes or series of those things and motions which are
for the most part unobserved except in their end or periods; the fourth provide
the sense with some substitute when it utterly fails; the fifth excite the
attention and notice of the sense, and at the same time set bounds to the
subtlety of things. Of these I shall now speak in their order. XXXIX Among Prerogative Instances I will put in the sixteenth place Instances of
the Door or Gate, this being the name I give to instances which aid the
immediate actions of the senses. Now of all the senses it is manifest that sight
has the chief office in giving information. This is the sense, therefore, for
which we must chiefly endeavor to procure aid. Now the aids to sight are of
three kinds: it may be enabled to perceive objects that are not visible; to
perceive them further off; and to perceive them more exactly and distinctly. Of the first kind (not to speak of spectacles and the like, which serve only
to correct or relieve the infirmity of a defective vision, and therefore give no
more information) are those recently invented glasses which disclose the latent
and invisible minutiae of bodies and their hidden configurations and motions by
greatly increasing their apparent size; instruments by the aid of which the
exact shape and outline of body in a flea, a fly, a worm, and also colors and
motions before unseen, are not without astonishment discerned. It is also said
that a straight line drawn with a pen or pencil is seen through such glasses to
be very uneven and crooked, the fact being that neither the motion of the hand,
though aided by a ruler, nor the impression of the ink or color, is really even,
although the unevenness is so minute that it cannot be detected without such
glasses. And here (as is usual in things new and wonderful) a kind of
superstitious observation has been added, viz., that glasses of this sort do
honor to the works of nature but dishonor to the works of art. The truth however
is only this, that natural textures are far more subtle than artificial. For the
microscope, the instrument I am speaking of, is only available for minute
objects. So that if Democritus had seen one, he would perhaps have leaped for
joy, thinking a way was now discovered of discerning the atom, which he had
declared to be altogether invisible. The incompetency however of such glasses,
except for minutiae alone, and even for them when existing in a body of
considerable size, destroys the use of the invention. For if it could be
extended to larger bodies, or to the minutiae of larger bodies, so that the
texture of a linen cloth could be seen like network, and thus the latent
minutiae and inequalities of gems, liquors, urine, blood, wounds, etc., could be
distinguished, great advantages might doubtless be derived from the discovery. Of the second kind are those other glasses discovered by the memorable
efforts of Galileo, by the aid of which, as by boats or vessels, a nearer
intercourse with the heavenly bodies can be opened and carried on. For these
show us that the Milky Way is a group or cluster of small stars entirely
separate and distinct, of which fact there was but a bare suspicion among the
ancients. They seem also to point out that the spaces of the planetary orbits,
as they are called, are not altogether destitute of other stars, but that the
heaven begins to be marked with stars before we come to the starry sphere
itself, although with stars too small to be seen without these glasses. With
this instrument we can descry those small stars wheeling as in a dance round the
planet Jupiter, whence it may be conjectured that there are several centers of
motion among the stars. With this the inequalities of light and shade in the
moon are more distinctly seen and placed, so that a sort of selenography can be
made. With this we descry spots on the sun, and similar phenomena — all indeed
noble discoveries, so far as we may safely trust to demonstrations of this kind,
which I regard with suspicion chiefly because the experiment stops with these
few discoveries, and many other things equally worthy of investigation are not
discovered by the same means. Of the third kind are measuring rods, astrolabes, and the like, which do not
enlarge the sense of sight, but rectify and direct it. And if there are other
instances which aid the remaining senses in their immediate and individual
actions, and yet are of a kind which add nothing to the information already
possessed; they are not to the present purpose, and therefore I have omitted to
mention them. XL Among Prerogative Instances I will put in the seventeenth place Summoning
Instances, borrowing the name from the courts of law, because they summon
objects to appear which have not appeared before. I also call them Evoking
Instances. They are those which reduce the nonsensible to the sensible, that
is, make manifest things not directly perceptible by means of others which are. An object escapes the senses either on account of its distance; or on account
of the interposition of intermediate bodies; or because it is not fitted for
making an impression on the sense; or because it is not sufficient in quantity
to strike the sense; or because there is not time enough for it to act on the
sense; or because the impression of the object is such as the sense cannot bear;
or because the sense has been previously filled and occupied by another object,
so that there is not room for a new motion. These cases have reference
principally to the sight, and secondarily to the touch. For these two senses
give information at large and concerning objects in general, whereas the other
three give hardly any information but what is immediate and relates to their
proper objects. In the first kind, where an object is imperceptible by reason of its
distance, there is no way of manifesting it to the sense but by joining to it or
substituting for it some other object which may challenge and strike the sense
from a greater distance — as in communication by beacons, bells, and the like. In the second kind, this reduction or secondary manifestation is effected
when objects that are concealed by the interposition of bodies within which they
are enclosed and cannot conveniently be opened out are made manifest to the
sense by means of those parts of them which lie on the surface, or make their
way from the interior. Thus the condition of the human body is known by the
state of the pulse, urine, and the like. In the third and fourth kind, reductions are applicable to a great many
things, and in the investigations of nature should be sought for on all sides.
For example, it is obvious that air and spirit, and like bodies, which in their
entire substance are rare and subtle, can neither be seen nor touched.
Therefore, in the investigation of bodies of this kind it is altogether
necessary to resort to reductions. Thus let the nature in question be the action and motion of the spirit
enclosed in tangible bodies. For everything tangible that we are acquainted with
contains an invisible and intangible spirit which it wraps and clothes as with a
garment. Hence that three-fold source, so potent and wonderful, of the process
of the spirit in a tangible body. For the spirit in a tangible substance, if
discharged, contracts bodies and dries them up; if detained, softens and melts
them; if neither wholly discharged nor wholly detained, gives them shape,
produces limbs, assimilates, digests, ejects, organizes, and the like. And all
these processes are made manifest to the sense by conspicuous effects. For in every tangible inanimate body the enclosed spirit first multiplies
itself and, as it were, feeds upon those tangible parts which are best disposed
and prepared for that purpose and so digests and elaborates and turns them into
spirit; and then they escape together. Now this elaboration and multiplication
of the spirit is made manifest to the sense by diminution of weight. For in all
desiccation there is some decrease of quantity, not only of the quantity of
spirit previously existing in the body, but also of the body itself, which was
before tangible and is newly changed. For spirit is without weight. Now the
discharge or emission of the spirit is made manifest to the sense in the rust of
metals and other similar putrefactions which stop short before they come to the
rudiments of life; for these belong to the third kind of process. For in compact
bodies the spirit finds no pores or passages through which to escape and is
therefore compelled to push and drive before it the tangible parts themselves,
so that they go out along with it; whence proceed rust and the like. On the
other hand the contraction of the tangible parts after some of the spirit is
discharged (upon which desiccation ensues), is made manifest to the sense not
only by the increased hardness of the body, but much more by the rents,
contractions, wrinklings, and shrivelings in the body which thereupon take
place. For the parts of wood split asunder and are contracted; skins shrivel;
and not only that, but if the spirit is suddenly discharged by the heat of fire,
they hasten so fast to contraction as to curl and roll themselves up. On the contrary, where the spirit is detained and yet expanded and excited by
heat or something analogous thereto (as happens in the more solid or tenacious
bodies), then are bodies softened, as white hot iron; or they become fluid, as
metals; or liquid, as gums, wax, and the like. Thus the contrary operations of
heat, which hardens some substances and melts others, are easily reconciled,
since in the former the spirit is discharged, in the latter it is excited and
detained; whereof the melting is the proper action of the heat and spirit, the
hardening is the action of the tangible parts only on occasion of the discharge
of the spirit. But when the spirit is neither wholly detained nor wholly discharged, but
only makes trials and experiments within its prison house, and meets with
tangible parts that are obedient and ready to follow, so that wheresoever the
spirit leads they go along with it, then ensues the forming of an organic body
and the development of organic parts, and all the other vital actions as well in
vegetable as in animal substances. And these operations are made manifest to the
sense chiefly by careful observation of the first beginnings and rudiments or
essays of life in animalculae generated from putrefaction, as in ants' eggs,
worms, flies, frogs after rain, etc. There is required, however, for the
production of life both mildness in the heat and pliancy in the substance, that
the spirit may neither be so hurried as to break out, nor be confined by the
obstinacy of the parts, but may rather be able to mold and model them like wax. Again, that most noble distinction of spirit which has so many applications
(viz., spirit cut off; spirit simply branching; spirit at once branching and
cellulate — of which the first is the spirit of all inanimate substances, the
second of vegetables, the third of animals), is brought as it were before the
eyes by several instances of this kind of reduction. In like manner it appears that the more subtle textures and configurations of
things (though the entire body be visible or tangible) are perceptible neither
to the sight nor touch. And therefore in these also, our information comes by
way of reduction. Now the most radical and primary difference between
configurations is drawn from the abundance or scantiness of the matter occupying
the same space or dimensions. For all other configurations (which have reference
to the dissimilarity of the parts contained in the same body, and to their
collocation and position) are but secondary in comparison with the former. Thus let the nature in question be the expansion or coition of matter in
bodies compared one with another, viz., how much matter occupies how much space
in each. For there is nothing more true in nature than the twin propositions
that "nothing is produced from nothing," and "nothing is reduced to nothing,"
but that the absolute quantum or sum total of matter remains unchanged, without
increase or diminution. Nor is it less true that of that quantum of matter more
or less is contained under the same space or dimensions according to the
diversity of bodies; as in water more, in air less. So that to assert that a
given volume of water can be changed into an equal volume of air is as much as
to say that something can be reduced to nothing; as on the other hand to
maintain that a given volume of air can be turned into an equal volume of water
is the same as to say that something can be produced out of nothing. And it is
from this abundance and scantiness of matter that the abstract notions of dense
and rare, though variously and promiscuously used, are, properly speaking,
derived. We must also take for granted a third proposition which is also
sufficiently certain, viz., that this greater or less quantity of matter in this
or that body is capable of being reduced by comparison to calculation and to
exact or nearly exact proportions. Thus one would be justified in asserting that
in any given volume of gold there is such an accumulation of matter, that spirit
of wine, to make up an equal quantity of matter, would require twenty-one times
the space occupied by the gold. Now the accumulation of matter and its proportions are made manifest to the
sense by means of weight. For the weight answers to the quantity of matter in
the parts of a tangible body, whereas spirit and the quantum of matter which it
contains cannot be computed by weight, for it rather diminishes the weight than
increases it. But I have drawn up a very accurate table on this subject, in
which I have noted down the weights and volumes of all the metals, the principal
stones, woods, liquors, oils, and many other bodies, natural as well as
artificial — a thing of great use in many ways, as well for light of information
as for direction in practice, and one that discloses many things quite beyond
expectation. Not the least important of which is this — it shows that all the
variety in tangible bodies known to us (such bodies I mean as are tolerably
compact and not quite spongy and hollow, and chiefly filled with air) does not
exceed the limit of the ratio of 1 to 21 — so limited is nature, or at any rate
that part of it with which we have principally to do. I have also thought it worth while to try whether the proportions can be
calculated which intangible or pneumatic bodies bear to bodies tangible. This I
attempted by the following contrivance. I took a glass phial, capable of holding
about an ounce, using a small vessel that less heat might be required to produce
evaporation. This phial I filled with spirit of wine almost to the neck,
selecting spirit of wine, because I found by the former table that of all
tangible bodies (which are well united and not hollow) this is the rarest and
contains the least quantity of matter in a given space. After that, I noted
exactly the weight of the spirit and phial together. I then took a bladder
capable of holding about a quart from which I squeezed out, as well as I could,
all the air, until the two sides of the bladder met. The bladder I had
previously rubbed over gently with oil, to make it closer, and having thus
stopped up the pores, if there were any, I inserted the mouth of the phial
within the mouth of the bladder, and tied the latter tightly round the former
with a thread smeared with wax in order that it might stick more closely and tie
more firmly. After this I set the phial on a chafing dish of hot coals.
Presently the steam or breath of the spirit of wine, which was dilated and
rendered pneumatic by the heat, began gradually to expand the bladder and
swelled it out on all sides like a sail. When this took place, I immediately
took the glass off the fire, placing it on a carpet that it might not crack with
the cold, at the same time making a hole in the bladder lest the steam should
turn liquid again on the cessation of the heat and so disturb the calculations.
I then removed the bladder, and weighing the spirit of wine which remained,
computed how much had been converted into steam or air. Then, comparing the
space which the body had occupied while it was spirit of wine in the phial with
the space which it afterward occupied when it had become pneumatic in the
bladder, I computed the results, which showed clearly that the body had acquired
by the change a degree of expansion a hundred times greater than it had had
before. Again, let the nature in question be heat or cold, in a degree too weak to be
perceptible to the sense. These are made manifest to the sense by a calendar
glass such as I have described above. For the heat and cold are not themselves
perceptible to the touch, but the heat expands the air, and the cold contracts
it. Nor again is this expansion and contraction of the air perceptible to the
sight, but the expansion of the air depresses the water, the contraction raises
it, and so at last is made manifest to the sight; not before, nor otherwise. Again, let the nature in question be the mixture of bodies, viz., what they
contain of water, oil, spirit, ash, salt, and the like; or (to take a particular
instance) what quantity of butter, curd, whey, etc., is contained in milk. These
mixtures, so far as relates to tangible elements, are made manifest to the sense
by artificial and skillful separations. But the nature of the spirit in them,
though not immediately perceived, is yet discovered by the different motions and
efforts of the tangible bodies in the very act and process of their separation
and also by the acridities and corrosions, and by the different colors, smells,
and tastes of the same bodies after separation. And in this department men have
labored hard, it is true, with distillations and artificial separations, but not
with much better success than in the other experiments which have been hitherto
in use. For they have but groped in the dark and gone by blind ways and with
efforts painstaking rather than intelligent, and (what is worst of all), without
attempting to imitate or emulate nature, but rather destroying by the use of
violent heats and overstrong powers all that more subtle configuration in which
the occult virtues and sympathies of things chiefly reside. Nor do they remember
or observe, while making such separations, the circumstances which I have
elsewhere pointed out, namely, that when bodies are tormented by fire or other
means, many qualities are communicated by the fire itself and by the bodies
employed to effect the separation which did not exist previously in the
compound; whence strange fallacies have arisen. For it must not be supposed that
all the vapor which is discharged from water by the action of fire was formerly
vapor or air in the body of the water, the fact being that the greatest part of
it was created by the expansion of the water from the heat of the fire. So in general, all the nice tests of bodies whether natural or artificial by
which the genuine are distinguished from the adulterated, the better from the
viler sort, should be referred to this division; for they make manifest to the
sense things not directly perceptible by means of those which are. They should
therefore be sought and collected from all quarters with diligent care. With regard to the fifth way in which objects escape the sense, it is obvious
that the action of sense takes place in motion, and that motion takes place in
time. If therefore the motion of any body be either so slow or so quick that it
bears no proportion to the moments which the sense takes to act in, the object
is not perceived at all, as in the motion of the hand of a clock and again in
the motion of a musket ball. Now motion which is too slow to be perceived is
easily and usually made manifest to the sense by means of aggregates of motion.
Motion which is too quick has not hitherto been competently measured, and yet
the investigation of nature requires that this be done in some cases. In the sixth kind, where the sense is hindered by the too great power of the
object, the reduction may be effected either by removing the object to a greater
distance from the sense; or by deadening its effects by the interposition of a
medium which will weaken without annihilating the object; or by admitting and
receiving the reflection of the object where the direct impression is too
powerful, as that of the sun, for instance, in a basin of water. The seventh cause, where the sense is so charged with one object that it has
no room for the admission of another, is almost wholly confined to the sense of
smell and has little to do with the matter in hand. So much then for the
reduction of the nonsensible to the sensible — or the modes of making manifest
to the sense things not directly perceptible by means of others which are. Sometimes, however, the reduction is made not to the sense of a man, but of
some other animal whose sense in some cases is keener than man's; as of certain
scents to the sense of a dog; of the light which is latent in air when not
illumined from without to the sense of a cat, owl, and similar animals which see
in the dark. For Telesius has justly observed that there is in the air itself a
certain original light, though faint and weak, and hardly of any use to the eyes
of men and most animals; inasmuch as animals to whose sense this light is
adapted see in the dark, which it is hardly to be believed they do either
without light, or by a light within. Observe also that at present I am dealing with the deficiencies of the senses
and their remedies. The deceptions of the senses must be referred to the
particular inquiries concerning sense and the objects of sense, excepting only
that grand deception of the senses, in that they draw the lines of nature with
reference to man and not with reference to the universe; and this is not to be
corrected except by reason and universal philosophy. XLI Among Prerogative Instances I will put in the eighteenth place Instances
of the Road, which I also call Traveling Instances and Articulate
Instances. They are those which point out the motions of nature in their
gradual progress. This class of instances escapes the observation rather than
the sense. For it is strange how careless men are in this matter; for they study
nature only by fits and at intervals, and when bodies are finished and
completed, not while she is at work upon them. Yet if anyone were desirous of
examining and studying the contrivances and industry of an artificer, he would
not be content with beholding merely the rude materials of the art and then the
completed works, but would rather wish to be present while the artificer was at
his labors and carrying his work on. And a like course should be taken with the
investigation of nature. For instance, if we are inquiring into the vegetation
of plants, we must begin from the very sowing of the seed, and observe (as we
may easily do, by taking out day after day the seeds that have lain in the
ground two days, three days, four days, and so on, and carefully examining them)
how and when the seed begins to puff and swell and to be, as it were, filled
with spirit; secondly, how it begins to burst the skin and put forth fibers, at
the same time raising itself slightly upwards, unless the ground be very stiff;
also, how it puts forth its fibers, some for the root downwards and some for the
stem upwards, and sometimes also creeping sideways if it there finds the ground
more open and yielding; and so with many other things of the kind. In the same
way we should examine the hatching of eggs, in which we might easily observe the
whole process of vivification and organization, and see what parts proceed from
the yolk and what from the white of the egg, and so forth. A similar course
should be taken with animals generated from putrefaction. For to prosecute such
inquiries concerning perfect animals by cutting out the fetus from the womb
would be too inhuman, except when opportunities are afforded by abortions, the
chase, and the like. There should therefore be set a sort of night watch over
nature, as showing herself better by night than by day. For these may be
regarded as night studies by reason of the smallness of our candle and its
continual burning. The same too should be attempted with inanimate substances, as I have done
myself in investigating the expansion of liquids by fire. For there is one mode
of expansion in water, another in wine, another in vinegar, another in verjuice,
and quite another in milk and oil; as was easily to be seen by boiling them over
a slow fire and in a glass vessel in which everything may be clearly
distinguished. These matters, however, I touch but briefly, meaning to treat of
them more fully and exactly when I come to the discovery of the Latent
Process of things. For it should all along be borne in mind that in this
place I am not handling the things themselves, but only giving examples. XLII Among Prerogative Instances I will put in the nineteenth place
Supplementary or Substitutive Instances, which I also call
Instances of Refuge. They are those which supply information when the senses
entirely fail us, and therefore we fly to them when appropriate instances are
not to be had. Now substitution is made in two ways: either by gradual
approximation or by analogy. To take an example: There is no medium known by the
interposition of which the operation of the magnet in drawing iron is entirely
prevented. Gold placed between does not stop it, nor silver, nor stone, nor
glass, wood, water, oil, cloth or fibrous substances, air, flame, etc. But yet
by nice tests some medium may possibly be found to deaden its virtue more than
any other; comparatively, that is, and in some degree. Thus it may be that the
magnet would not attract iron as well through a mass of gold as through an equal
space of air, or through ignited silver as well as through cold; and so in other
cases. For I have not made the trial myself in these cases. It is enough to
propose such experiments by way of example. Again, there is no body we are
acquainted with which does not contract heat on being brought near the fire. And
yet air contracts heat much more quickly than stone. Such is the substitution
which is made by gradual approximation. Substitution by analogy is doubtless useful, but is less certain, and should
therefore be applied with some judgment. It is employed when things not directly
perceptible are brought within reach of the sense, not by perceptible operations
of the imperceptible body itself, but by observation of some cognate body which
is perceptible. For example, suppose we are inquiring into the mixture of
spirits, which are invisible bodies. There seems to be a certain affinity
between bodies and the matter that feeds or nourishes them. Now the food of
flame seems to be oil and fat substances; of air, water and watery substances;
for flame multiplies itself over exhalations of oil, air over the vapor of
water. We should therefore look to the mixture of water and oil, which manifests
itself to the sense, since the mixture of air and flame escapes the sense. Now
oil and water, which are mingled together very imperfectly by composition or
agitation, are in herbs and blood and the parts of animals very subtly and
finely mingled. It is possible, therefore, that something similar may be the
case with the mixture of flame and air in pneumatic bodies, which, though not
readily mingling by simple commixture, yet seem to be mingled together in the
spirits of plants and animals, especially as all animate spirit feeds on moist
substances of both kinds, watery and fat, as its proper food. Again, if the inquiry be not into the more perfect mixtures of pneumatic
bodies but simply into their composition, that is, whether they be readily
incorporated together; or whether there be not rather, for example, certain
winds and exhalations or other pneumatic bodies which do not mix with common
air, but remain suspended and floating therein in globules and drops and are
rather broken and crushed by the air than admitted into or incorporated with it
— this is a thing which cannot be made manifest to the senses in common air and
other pneumatic bodies, by reason of their subtlety. Yet how far the thing may
take place we may conceive, by way of image or representation, from what takes
place in such liquids as quicksilver, oil, or water, and likewise from the
breaking up of air when it is dispersed in water and rises in little bubbles;
and again in the thicker kinds of smoke; and lastly, in dust raised and floating
in the air; in all of which cases no incorporation takes place. Now the
representation I have described is not a bad one for the matter in question,
provided that diligent inquiry has been first made whether there can be such a
heterogeneity in pneumatic bodies as we find there is in liquids. For if there
can, then these images by analogy may not inconveniently be substituted. But with regard to these supplementary instances, although I stated that
information was to be derived from them in the absence of instances proper, as a
last resource, yet I wish it to be understood that they are also of great use
even when proper instances are at hand — for the purpose, I mean, of
corroborating the information which the others supply. But I shall treat of them
more fully when I come in due course to speak of the Supports of Induction. XLIII Among Prerogative Instances I will put in the twentieth place Dissecting
Instances, which I also call Awakening Instances, but for a different
reason. I call them awakening, because they awaken the understanding;
dissecting, because they dissect nature. For which reason also I sometimes call
them Democritean. They are those which remind the understanding of the
wonderful and exquisite subtlety of nature, so as to stir it up and awaken it to
attention and observation and due investigation. Such, for example, as these
following: that a little drop of ink spreads to so many letters or lines; that
silver gilt stretches to such a length of gilt wire; that a tiny worm, such as
we find in the skin, possesses in itself both spirit and a varied organization;
that a little saffron tinges a whole hogshead of water; that a little civet or
musk scents a much larger volume of air; that a little incense raises such a
cloud of smoke; that such exquisite differences of sounds, as articulate words,
are carried in every direction through the air, and pierce even, though
considerably weakened, through the holes and pores of wood and water, and are
moreover echoed back, and that too with such distinctness and velocity; that
light and color pass through the solid substances of glass and water so
speedily, and in so wide an extent, and with such copious and exquisite variety
of images, and are also refracted and reflected; that the magnet acts through
bodies of all sorts, even the most compact; and yet (which is more strange) that
in all these, passing as they do through an indifferent medium (such as the air
is), the action of one does not much interfere with the action of another. That
is to say, that at the same time there are carried through spaces of air so many
images of visible objects, so many impressions of articulate sound, so many
distinct odors, as of a violet, rose, etc.; moreover, heat and cold and magnetic
influences — all (I say) at once without impeding one another, just as if they
had their own roads and passages set apart, and none ever struck or ran against
other. To these dissecting instances it is useful however to subjoin instances
which I call limits of dissection, as that in the cases above mentioned, though
one action does not disturb or impede another action of a different kind, yet
one action does overpower and extinguish another action of the same kind; as the
light of the sun extinguishes that of a glowworm; the report of a cannon drowns
the voice; a strong scent overpowers a more delicate one; an intense heat a
milder one; a plate of iron interposed between a magnet and another piece of
iron destroys the action of the magnet. But this subject also will find its
proper place among the supports of induction. XLIV So much for instances which aid the senses, instances which are chiefly
useful for the informative part of our subject. For information commences with
the senses. But the whole business terminates in works, and as the former is the
beginning, so the latter is the end of the matter. I will proceed therefore with
the instances which are pre-eminently useful for the operative part. They are of
two kinds, and seven in number, though I call them all by the general name of
Practical Instances. In the operative part there are two defects and two
corresponding prerogatives of instances. For operation either fails us or it
overtasks us. The chief cause of failure in operation (especially after natures
have been diligently investigated) is the ill determination and measurement of
the forces and actions of bodies. Now the forces and actions of bodies are
circumscribed and measured, either by distances of space, or by moments of time,
or by concentration of quantity, or by predominance of virtue. And unless these
four things have been well and carefully weighed we shall have sciences fair
perhaps in theory, but in practice inefficient. The four instances which are
useful in this point of view I class under one head as Mathematical Instances
and Instances of Measurement. Operation comes to overtask us, either through the admixture of useless
matters, or through the multiplicity of instruments, or through the bulk of the
material and of the bodies that may happen to be required for any particular
work. Those instances therefore ought to be valued which either direct practice
to the objects most useful to mankind; or which save instruments; or which spare
material and provision. The three instances which serve us here I class together
as Propitious or Benevolent Instances. These seven instances I
will now discuss separately, and with them conclude that division of my subject
which relates to the Prerogative or Rank of Instances. XLV Among Prerogative Instances I will put in the twenty-first place Instances
of the Rod or Rule, which I also call Instances of Range or of
Limitation. For the powers and motions of things act and take effect at
distances not indefinite or accidental, but finite and fixed; so that to
ascertain and observe these distances in the investigation of the several
natures is of the greatest advantage to practice, not only to prevent its
failure but also to extend and increase its power. For we are sometimes enabled
to extend the range of powers and, as it were, to diminish distances, as for
instance by the use of telescopes. Most of these powers act and take effect only by manifest contact, as in the
impact of two bodies, where the one does not move the other from its place
unless they touch each other. Also medicines that are applied externally, as
ointments or plasters, do not exert their virtues without touching the body.
Finally, the objects of the taste and touch do not strike those senses unless
they be contiguous to the organs. There are also powers which act at a distance, though a very small one; and
of these only a few have been hitherto observed, albeit there are many more than
men suspect; as (to take common examples) when amber or jet attracts straws;
bubbles dissolve bubbles on being brought together; certain purgative medicines
draw humors downward, and the like. So, too, the magnetic power by which iron
and a magnet, or two magnets, are made to meet, operates within a fixed but
narrow sphere of action; but if there be any magnetic virtue flowing from the
earth (a little below the surface), and acting on a steel needle in respect of
its polarity, the action operates at a great distance. Again, if there be any magnetic power which operates by consent between the
globe of the earth and heavy bodies, or between the globe of the moon and the
waters of the sea (as seems highly probable in the semimenstrual ebbs and
floods), or between the starry sphere and the planets whereby the latter are
attracted to their apogees, all these must operate at very great distances.
There are found also certain materials which catch fire a long way off, as we
are told the naphtha of Babylon does. Heat also insinuates itself at great
distances, as also does cold; insomuch that by the inhabitants of Canada the
masses of ice that break loose and float about the northern ocean and are borne
through the Atlantic toward that coast are perceived at a great distance by the
cold they give out. Perfumes also (though in these there appears to be always a
certain corporeal discharge) act at remarkable distances, as those find who sail
along the coasts of Florida or some parts of Spain, where there are whole woods
of lemon and orange and like odoriferous trees, or thickets of rosemary,
marjoram, and the like. Lastly, the radiations of light and impressions of sound
operate at vast distances. But whether the distances at which these powers act be great or small, it is
certain that they are all finite and fixed in the nature of things, so that
there is a certain limit never exceeded, and a limit which depends either on the
mass or quantity of matter in the bodies acted on; or on the strength or
weakness of the powers acting; or on the helps or hindrances presented by the
media in which they act — all which things should be observed and brought to
computation. Moreover, the measurements of violent motions (as they are called),
as of projectiles, guns, wheels, and the like, since these also have manifestly
their fixed limits, should be observed and computed. There are found also certain motions and virtues of a contrary nature to
those which operate by contact and not at a distance, namely, those which
operate at a distance and not by contact; and again those which operate more
feebly at a lesser distance, and more powerfully at a greater. The act of sight
for instance is not well performed in contact but requires a medium and a
distance. Yet I remember being assured by a person of veracity that he himself
under an operation for the cataract, when a small silver needle was inserted
within the first coat of the eye in order to remove the pellicle of the cataract
and push it into a corner, saw most distinctly the needle passing over the very
pupil. But though this may be true, it is manifest that large bodies are not
well or distinctly seen except at the vertex of a cone, the rays from the object
converging at a certain distance from it. Moreover, old people see objects
better at a little distance than if quite close. In projectiles, too, it is
certain that the impact is not so violent at too small a distance as it is a
little further off. These, therefore, and like things should be observed in the
measurements of motions with regard to distances. There is also another kind of local measurement of motions which must not be
omitted. This has to do with motions not progressive, but spherical, that is,
with the expansion of bodies into a greater sphere or their contraction into a
less. For among our measurements of motions we must inquire what degree of
compression or extension bodies (according to their nature) easily and freely
endure, and at what point they begin to resist, till at last they will bear no
more. Thus, when a blown bladder is compressed, it allows a certain compression
of the air, but if the compression be increased the air does not endure it and
the bladder bursts. But this same thing I have tested more accurately by a subtle experiment. I
took a small bell of metal, light and thin, such as is used for holding salt,
and plunged it into a basin of water so that it carried down with it the air
contained in its cavity to the bottom of the basin, where I had previously
placed a small globe, on which the bell was to light. I found then that if the
globe was small enough in proportion to the cavity, the air contracted itself
into a less space and was simply squeezed together, not squeezed out. But if it
was too large for the air to yield freely, then the air, impatient of greater
pressure, raised the bell on one side and rose to the surface in bubbles. Again, to test the extension as well as compression of which air was
susceptible, I had recourse to the following device. I took a glass egg with a
small hole at one end of it, and, having drawn out the air through the hole by
violent suction, I immediately stopped up the hole with my finger and plunged
the egg into water, and then took away my finger. The air, having been extended
by the suction and dilated beyond its natural dimensions, and therefore
struggling to contract itself again (so that if the egg had not been plunged
into the water it would have drawn in air with a hissing sound), now drew in
water in sufficient quantities to allow the air to recover its old sphere or
dimension. Now it is certain that the rarer bodies (such as air) allow a considerable
degree of contraction, as has been stated, but that tangible bodies (such as
water) suffer compression with much greater difficulty and to a lesser extent.
How far they do suffer it I have investigated in the following experiment. I had
a hollow globe of lead made, capable of holding about two pints, and
sufficiently thick to bear considerable force. Having made a hole in it, I
filled it with water and then stopped up the hole with melted lead, so that the
globe became quite solid. I then flattened two opposite sides of the globe with
a heavy hammer, by which the water was necessarily contracted into less space, a
sphere being the figure of largest capacity. And when the hammering had no more
effect in making the water shrink, I made use of a mill or press, till the
water, impatient of further pressure, exuded through the solid lead like a fine
dew. I then computed the space lost by the compression and concluded that this
was the extent of compression which the water had suffered, but only when
constrained by great violence. But the compression or extension endured by more solid, dry, or more compact
bodies, such as wood, stones and metals, is still less than this, and scarcely
perceptible. For they free themselves either by breaking, or by moving forward,
or by other efforts, as is apparent in the bending of wood or metal, in clocks
moving by springs, in projectiles, hammerings, and numberless other motions. And
all these things with their measures should in the investigation of nature be
explored and set down, either in their certitude, or by estimate, or by
comparison, as the case will admit. XLVI Among Prerogative Instances I will put in the twenty-second place
Instances of the Course, which I also call Instances of the Water,
borrowing the term from the hourglasses of the ancients, which contained water
instead of sand. These measure nature by periods of time, as the instances of
the rod by degrees of space. For all motion or natural action is performed in
time, some more quickly, some more slowly, but all in periods determined and
fixed in the nature of things. Even those actions which seem to be performed
suddenly and (as we say) in the twinkling of an eye, are found to admit of
degree in respect to duration. First, then, we see that the revolutions of heavenly bodies are accomplished
in calculated times, as also the flux and reflux of the sea. The motion of heavy
bodies to the earth, and of light bodies toward the heavens, is accomplished in
definite periods, varying with the bodies moved and the medium through which
they move. The sailing of ships, the movements of animals, the transmission of
missiles, are all performed likewise in times which admit (in the aggregate) of
measurement. As for heat, we see boys in wintertime bathe their hands in flame
without being burned, and jugglers by nimble and equable movements turn vessels
full of wine or water upside down and then up again without spilling the liquid;
and many other things of a similar kind. The compressions also and expansions
and eruptions of bodies are performed, some more quickly, some more slowly,
according to the nature of the body and motion, but in certain periods. Moreover, in the explosion of several guns at once, which are heard sometimes
to the distance of thirty miles, the sound is caught by those who are near the
spot where the discharge is made sooner than by those who are at a greater
distance. Even in sight, whereof the action is most rapid, it appears that there
are required certain moments of time for its accomplishment, as is shown by
those things which by reason of the velocity of their motion cannot be seen — as
when a ball is discharged from a musket. For the ball flies past in less time
than the image conveyed to the sight requires to produce an impression. This fact, with others like it, has at times suggested to me a strange doubt,
viz., whether the face of a clear and starlit sky be seen at the instant at
which it really exists, and not a little later; and whether there be not, as
regards our sight of heavenly bodies, a real time and an apparent time, just
like the real place and apparent place which is taken account of by astronomers
in the correction for parallaxes. So incredible did it appear to me that the
images or rays of heavenly bodies could be conveyed at once to the sight through
such an immense space and did not rather take a perceptible time in traveling to
us. But this suspicion as to any considerable interval between the real time and
the apparent afterward vanished entirely when I came to think of the infinite
loss and diminution of quantity which distance causes in appearance between the
real body of the star and its seen image; and at the same time when I observed
the great distance (sixty miles at the least) at which bodies merely white are
instantly seen here on earth; while there is no doubt that the light of heavenly
bodies exceeds many times over in force of radiation not merely the vivid color
of whiteness, but also the light of every flame that is known to us. Again, the
immense velocity in the body itself as discerned in its daily motion (which has
so astonished certain grave men that they preferred believing that the earth
moved) renders this motion of ejaculation of rays therefrom (although wonderful,
as I have said, in speed) more easy of belief. But what had most weight of all
with me was that if any perceptible interval of time were interposed between the
reality and the sight, it would follow that the images would oftentimes be
intercepted and confused by clouds rising in the meanwhile, and similar
disturbances in the medium. And thus much for the simple measures of time. But not only must we seek the measure of motions and actions by themselves
but much more in comparison, for this is of excellent use and very general
application. Now we find that the flash of a gun is seen sooner than its report
is heard, although the ball must necessarily strike the air before the flame
behind it can get out. And this is owing, it seems, to the motion of light being
more rapid than that of sound. We find, too, that visible images are received by
the sight faster than they are dismissed. Thus the strings of a violin when
struck by the finger are to appearance doubled or tripled, because a new image
is received before the old one is gone; which is also the reason why rings being
spun round look like globes, and a lighted torch, carried hastily at night,
seems to have a tail. And it was upon this inequality of motions in point of
velocity that Galileo built his theory of the flux and reflux of the sea,
supposing that the earth revolved faster than the water could follow, and that
the water therefore first gathered in a heap and then fell down, as we see it do
in a basin of water moved quickly. But this he devised upon an assumption which
cannot be allowed, viz., that the earth moves, and also without being well
informed as to the sexhorary motion of the tide. But an example of the thing I am treating of, to wit, the comparative
measures of motions — and not only of the thing itself, but also of its eminent
use (of which I spoke just now) — is conspicuous in mining with gunpowder where
vast masses of earth, buildings, and the like are upset and thrown into the air
by a very small quantity of powder. The cause of which is doubtless this: that
the motion of expansion in the impelling powder is quicker many times over than
the motion of the resisting gravity, so that the first motion is over before the
countermotion is begun, and thus at first the resistance amounts to nothing.
Hence too it happens that in projectiles it is not the strong blow but the sharp
and quick that carries the body furthest. Nor would it be possible for the small
quantity of animal spirit in animals, especially in such huge creatures as the
whale or elephant, to bend and guide such a vast mass of body were it not for
the velocity of the spirit's motion, and the slowness of the bodily mass in
exerting its resistance. This one thing indeed is a principal foundation of the experiments in natural
magic (of which I shall speak presently) wherein a small mass of matter
overcomes and regulates a far larger mass — I mean the contriving that of two
motions one shall by its superior velocity get the start and take effect before
the other has time to act. Lastly, this distinction of foremost and hindmost ought to be observed in
every natural action. Thus in an infusion of rhubarb the purgative virtue is
extracted first, the astringent afterward. And something of the kind I have
found on steeping violets in vinegar, where the sweet and delicate scent of the
flower is extracted first, and then the more earthy part of the flower, which
mars the scent. Therefore, if violets be steeped in vinegar for a whole day the
scent is extracted much more feebly, but if you keep them in for a quarter of an
hour only and then take them out, and (since the scented spirit in violets is
small) put in fresh violets every quarter of an hour as many as six times, the
infusion is at last so enriched that although there have not been violets in the
vinegar, however renewed, for more than an hour and a half altogether, there
nevertheless remains in it a most grateful odor, as strong as the violet itself,
for an entire year. It should be observed, however, that the odor does not
gather its full strength till after a month from the time of infusion. In the
distillation too of aromatic herbs crushed in spirit of wine, it appears that
there first rises an aqueous and useless phlegm, then a water containing more of
the spirit of wine, and lastly, a water containing more of the aroma. And of
this kind there are to be found in distillations a great many facts worthy of
notice. But let these suffice for examples. XLVII Among Prerogative Instances I will put in the twenty-third place Instances
of Quantity, which (borrowing a term from medicine) I also call Doses of
Nature. These are they which measure virtues according to the quantity
of the bodies in which they subsist and show how far the mode of the
virtue depends upon the quantity of the body. And first there are certain
virtues which subsist only in a cosmical quantity, that is, such a quantity as
has consent with the configuration and fabric of the universe. The earth for
instance stands fast; its parts fall. The waters in seas ebb and flow; but not
in rivers, except through the sea coming up. Secondly, almost all particular
virtues act according to the greater or less quantity of the body. Large
quantities of water corrupt slowly, small ones quickly. Wine and beer ripen and
become fit to drink much more quickly in bottles than in casks. If an herb be
steeped in a large quantity of liquid, infusion takes place rather than
impregnation; if in a small, impregnation rather than infusion. Thus in its
effect on the human body a bath is one thing, a slight sprinkling another. Light
dews, again, never fall in the air but are dispersed and incorporated with it.
And in breathing on precious stones you may see the slight moisture instantly
dissolved, like a cloud scattered by the wind. Once more, a piece of a magnet
does not draw so much iron as the whole magnet. On the other hand there are
virtues in which smallness of quantity has more effect, as in piercing, a sharp
point pierces more quickly than a blunt one; a pointed diamond cuts glass, and
the like. But we must not stay here among indefinites, but proceed to inquire what
proportion the quantity of a body bears to the mode of its virtue. For it
would be natural to believe that the one was equal to the other; so that if a
bullet of an ounce weight falls to the ground in a given time, a bullet of two
ounces ought to fall twice as quickly, which is not the fact. Nor do the same
proportions hold in all kinds of virtues, but widely different. These measures,
therefore, must be sought from experiment, and not from likelihood or
conjecture. Lastly, in all investigation of nature the quantity of body — the dose, as it
were — required to produce any effect must be set down, and cautions as to the
too little and too much be interspersed. XLVIII Among Prerogative Instances I will put in the twenty-fourth place
Instances of Strife, which I also call Instances of Predominance.
These indicate the mutual predominance and subjection of virtues: which of them
is stronger and prevails, which of them is weaker and gives way. For the motions
and efforts of bodies are compounded, decomposed, and complicated, no less than
the bodies themselves. I will therefore first propound the principal kinds of
motions or active virtues in order that we may be able more clearly to compare
them together in point of strength, and thereby to point out and designate more
clearly the instances of strife and predominance. Let the first motion be that motion of resistance in matter which is
inherent in each several portion of it, and in virtue of which it absolutely
refuses to be annihilated. So that no fire, no weight or pressure, no violence,
no length of time can reduce any portion of matter, be it ever so small, to
nothing, but it will ever be something, and occupy some space; and, to whatever
straits it may be brought, will free itself by changing either its form or its
place; or if this may not be, will subsist as it is; and will never come to such
a pass as to be either nothing or nowhere. This motion the Schoolmen (who almost
always name and define things rather by effects and incapacities than by inner
causes) either denote by the axiom "two bodies cannot be in one place," or call
"the motion to prevent penetration of dimensions." Of this motion it is
unnecessary to give examples, as it is inherent in every body. Let the second motion be what I call motion of connection, by which
bodies do not suffer themselves to be separated at any point from contact with
another body, as delighting in mutual connection and contact. This motion the
Schoolmen call "motion to prevent a vacuum," as when water is drawn up by
suction or in a pump; the flesh by cupping glasses; or when water stops without
running out in perforated jars unless the mouth of the jar be opened to let in
the air; and in numberless instances of a similar kind. Let the third motion be what I call motion of liberty, by which bodies
strive to escape from preternatural pressure or tension and to restore
themselves to the dimensions suitable to their nature. Of this motion also we
have innumerable examples, such as (to speak first of escape from pressure) the
motion of water in swimming, of air in flying, of water in rowing, of air in the
undulations of winds, of a spring in clocks — of which we have also a pretty
instance in the motion of the air compressed in children's popguns, when they
hollow out an alder twig or some such thing and stuff it up at both ends with a
piece of pulpy root or the like, and then with a ramrod thrust one of the roots
or whatever the stuffing be toward the other hole, from which the root at the
further end is discharged with a report, and that before it is touched by the
nearer root or the ramrod. As for bodies escaping from tension, this motion
displays itself in air remaining in glass eggs after suction; in strings, in
leather and in cloth, which recoil after tension, unless it has gained too great
strength by continuance; and in similar phenomena. This motion the Schoolmen
refer to under the name of "motion in accordance with the form of the element";
an injudicious name enough, since it is a motion which belongs not only to fire,
air, and water, but to every variety of solid substance, as wood, iron, lead,
cloth, parchment, etc.; each of which bodies has its own proper limit of
dimension out of which it cannot easily be drawn to any considerable extent. But
since this motion of liberty is of all the most obvious, and is of infinite
application, it would be a wise thing to distinguish it well and clearly. For
some very carelessly confuse this motion with the two former motions of
resistance and connection, the motion, that is, of escape from pressure with the
motion of resistance; of escape from tension with the motion of connection —
just as if bodies when compressed yield or expand, that there may not ensue
penetration of dimensions; and, when stretched, recoil and contract, that there
may not ensue a vacuum. Whereas if air when compressed had a mind to contract
itself to the density of water, or wood to the density of stone, there would be
no necessity for penetration of dimensions, yet there might be a far greater
compression of these bodies than they ever do actually sustain. In the same way,
if water had a mind to expand to the rarity of air, or stone to the rarity of
wood, there would be no need for a vacuum to ensue, and yet there might be
effected a far greater extension of these bodies than they ever do actually
sustain. Thus the matter is never brought to a penetration of dimensions or to a
vacuum, except in the extreme limits of condensation and rarefaction, whereas
the motions of which I speak stop far short of these limits, and are nothing
more than desires which bodies have for preserving themselves in their
consistencies (or, if the Schoolmen like, in their forms), and not suddenly
departing therefrom unless they be altered by gentle means, and with consent.
But it is far more necessary (because much depends upon it) that men should know
that violent motion (which we call mechanical, but which Democritus, who in
expounding his primary motions is to be ranked even below second-rate
philosophers, called motion of stripe) is nothing more than this motion of
liberty, that is, of escape from compression to relaxation. For either in a mere
thrust, or in flight through the air, there occurs no movement or change of
place until the parts of the body moved are acted upon and compressed by the
impelling body more than their nature will bear. Then, indeed, when each part
pushes against the next, one after the other, the whole is moved. And it not
only moves forward, but revolves at the same time, the parts seeking in that way
also to free themselves or to distribute the pressure more equally. And so much
for this motion. Let the fourth motion be that to which I have given the name of the motion of
matter, which is in some sort the converse of the last named motion. For
in the motion of liberty bodies dread, loathe, and shun a new dimension, or a
new sphere, or new expansion or contraction (which are all names for the same
thing), and strive with all their might to recoil, and recover their old
consistency. On the contrary, in this motion of matter bodies desire a new
sphere or dimension and aspire thereto readily and quickly, and sometimes, as in
the case of gunpowder, with most violent effort. Now the instruments of this
motion, not indeed the sole, but the most potent, or at any rate the most
common, are heat and cold. For instance, air, if expanded by tension, as by
suction in glass eggs, labors under a strong desire to recover itself. But if
heat be applied, it longs, on the contrary, to expand, and desires a new sphere
and passes into it readily as into a new form (so they phrase it); and after a
certain degree of expansion cares not to return, unless invited thereto by the
application of cold, which is not a return, but a renewed transmutation. In the
same way water, if made to contract by pressure, resists and wishes to become
such as it was, that is, larger. But if there intervene intense and continued
cold, it changes itself spontaneously and gladly to the density of ice; and if
the cold be continued long, without interruption from heat, as in grottoes and
caverns of some depth, it turns to crystal or some similar material and never
recovers its form. Let the fifth motion be the motion of continuity, by which I do not
mean simple and primary continuity with some other body (for that is the motion
of connection), but self-continuity in a given body. For it is most certain that
all bodies dread a solution of continuity, some more, some less, but all to a
certain extent. For while in hard bodies, as steel or glass, the resistance to
discontinuity is exceedingly strong, even in liquids, where it seems to
disappear or at all events to be very feeble, it is not altogether absent but is
certainly there, though in its lowest degree of power, and betrays itself in
very many experiments as in bubbles, in the roundness of drops, in the thin
threads of droppings from roofs, in the tenacity of glutinous bodies, and the
like. But most of all does this appetite display itself if an attempt be made to
extend the discontinuity to minute fragments. For in a mortar, after a certain
amount of pulverization, the pestle produces no further effect; water does not
penetrate into minute chinks; even air itself, notwithstanding its subtlety,
does not suddenly pass through the pores of solid vessels but only after long
insinuation. Let the sixth motion be that which I call motion for gain, or motion
of want. It is that by which bodies, when placed among quite
heterogeneous and hostile bodies, if they find an opportunity of escaping from
these and uniting themselves to others more cognate (though these others be such
as have no close union with them) do nevertheless embrace the latter and choose
them as preferable; and seem to view this connection in the light of a gam
(whence the term), as though they stood in need of such bodies. For instance,
gold or any other metal in the leaf does not like the surrounding air. If
therefore it meet with any thick tangible body (as a finger, paper, what you
will) it instantly sticks to it and is not easily torn away. So too paper,
cloth, and the like do not agree well with the air which is lodged in their
pores. They are therefore glad to imbibe water or other moisture and eject the
air. A piece of sugar too, or a sponge, if dipped at one end in water or wine,
while the other stands out far above the surface, draws the water or the wine
gradually upward. Hence we derive an excellent rule for opening and dissolving bodies. For (to
say nothing of corrosives and strong waters which open for themselves a way) if
there can be found a body proportioned to and more in harmony and affinity with
a given solid body than that with which it is as of necessity mixed, the solid
body immediately opens and relaxes itself, and shutting out or ejecting the
latter, receives the former into itself. Nor does this motion for gain act or
exist only in immediate contact. For electricity (of which Gilbert and others
after him have devised such stories) is nothing else than the appetite of a body
when excited by gentle friction — an appetite which does not well endure the air
but prefers some other tangible body, if it be found near at hand. Let the seventh motion be what I call the motion of the greater
congregation, by which bodies are carried toward masses of a like nature
with themselves — heavy bodies to the globe of the earth, light to the compass
of the heaven. This the Schoolmen have denoted by the name of natural motion
from superficial considerations; either because there was nothing
conspicuous externally which could produce such motion (and therefore they
supposed it to be innate and inherent in things themselves), or perhaps because
it never ceases. And no wonder; for the earth and heaven are ever there, whereas
the causes and origins of most other motions are sometimes absent, sometimes
present. Accordingly this motion, because it ceases not but when others cease is
felt instantly, they deem perpetual and proper, all others adscititious. This
motion, however, in point of fact is sufficiently weak and dull, being one
which, except in bodies of considerable bulk, yields and succumbs to all other
motions, as long as they are in operation. And though this motion has so filled
men's thoughts as to have put all others almost out of sight, yet it is but
little that they know about it, being involved in many errors with regard to it. Let the eighth motion be the motion of the lesser congregation, by
which the homogeneous parts in a body separate themselves from the heterogeneous
and combine together; by which also entire bodies from similarity of substance
embrace and cherish each other, and sometimes are attracted and collected
together from a considerable distance; as when in milk, after it has stood a
while, the cream rises to the top, while in wine the dregs sink to the bottom.
For this is not caused by the motion of heaviness and lightness only, whereby
some parts rise up and some sink down, but much more by a desire of the
homogeneous parts to come together and unite in one. Now this motion differs from the motion of want in two points. One is that in
the latter there is the stronger stimulus of a malignant and contrary nature,
whereas in this motion (provided there be nothing to hinder or fetter it) the
parts unite from friendship even in the absence of a foreign nature to stir up
strife. The other point is that the union is here closer and, as it were, with
greater choice. In the former, if only the hostile body be avoided, bodies not
closely related come together, whereas in the latter, substances are drawn
together by the tie of close relationship and, as it were, combine into one. And
this motion resides in all composite bodies and would readily show itself were
it not bound and restrained by other appetites and necessities in the bodies
which interfere with the union in question. Now the binding of this motion takes place generally in three ways: by the
torpor of bodies; by the check of a dominant body; and by external motions. Now,
for the torpor of bodies, it is certain that there resides in tangible
substances a certain sluggishness, more or less, and an aversion from change of
place; insomuch that, unless they be excited, they had rather remain as they are
than change for the better. Now this torpor is shaken off by the help of three
things: either by heat, or by the eminent virtue of some cognate body, or by
lively and powerful motion. And as for the help of heat, it is for this reason
that heat has been denned to be "that which separates Heterogeneous and
congregates Homogeneous parts"; a definition of the Peripatetics justly derided
by Gilbert, who says it is much the same as if a man were to be denned as that
which sows wheat and plants vines — for that it is, a definition simply by
effects, and those particular. But the definition has a worse fault, inasmuch as
these effects, such as they are, arise not from a peculiar property of heat, but
only indirectly (for cold does the same, as I shall afterwards show); being
caused by the desire of homogeneous parts to unite, heat simply aiding to shake
off the torpor which had previously bound the desire. As for the help derived
from the virtue of a cognate body, it is well seen in an armed magnet which
excites in iron the virtue of detaining iron by similarity of substance, the
torpor of the iron being cast off by the virtue of the magnet. And as for help
derived from motion, it is shown in wooden arrows, having their points also of
wood, which penetrate more deeply into wood than if they were tipped with steel,
owing to the similarity of substance, the torpor of the wood being shaken off by
the rapid motion. Of these two experiments I have spoken also in the Aphorism on
Clandestine Instances. That binding of the motion of the lesser congregation which is caused by the
restraint of a dominant body is seen in the resolution of blood and urine by
cold. For as long as those bodies are filled with the active spirit which, as
lord of the whole, orders and restrains the several parts of whatsoever sort, so
long the homogeneous parts do not meet together on account of the restraint. But
as soon as the spirit has evaporated, or been choked by cold, then the parts
being freed from restraint meet together in accordance with their natural
desire. And thus it happens that all bodies which contain an eager spirit (as
salts and the like) remain as they are, and are not resolved, owing to the
permanent and durable restraint of a dominant and commanding spirit. That binding of the motion of lesser congregation which is caused by external
motion is most conspicuous in the shaking of bodies to prevent putrefaction. For
all putrefaction depends on the assembling together of homogeneous parts, whence
there gradually ensues the corruption of the old form, as they call it, and the
generation of a new. For putrefaction, which paves the way for the generation of
a new form, is preceded by a dissolution of the old, which is itself a meeting
together of homogeneous parts. That, indeed, if not impeded, is simple
resolution. But if it be met by various obstacles there follow putrefactions,
which are the rudiments of a new generation. But if (which is the present
question) a frequent agitation be kept up by external motion, then indeed this
motion of uniting (which is a delicate and tender one, and requires rest from
things without) is disturbed and ceases, as we see happen in numberless
instances. For example, the daily stirring or flowing of water prevents it from
putrefying; winds keep off pestilence in the air; corn turned and shaken in the
granary remains pure; all things, in short, that are shaken outwardly are the
slower to putrefy inwardly. Lastly, I must not omit that meeting of the parts of bodies which is the
chief cause of induration and desiccation. For when the spirit, or moisture
turned to spirit, has escaped from some porous body (as wood, bone, parchment,
and the like), then the grosser parts are with stronger effort drawn and
collected together; whence ensues induration or desiccation, which I take to be
owing not so much to the motion of connection to prevent a vacuum as to this
motion of friendship and union. As for the meeting of bodies from a distance, that is a rare occurrence, and
yet it exists in more cases than are generally observed. We have illustrations
of it when bubble dissolves bubble; when medicines draw humors by similarity of
substance; when the chord of one violin makes the chord of another sound a
unison, and the like. I suspect also that this motion prevails in the spirits of
animals, though it be altogether unknown. At any rate it exists conspicuously in
the magnet and magnetized iron. And now that we are speaking of the motions of
the magnet, they ought to be carefully distinguished. For there are four virtues
or operations in the magnet which should not be confounded but kept apart,
although the wonder and admiration of men have mixed them up together. The first
is, the attraction of magnet to magnet, or of iron to magnet, or of magnetized
iron to iron. The second is its polarity, and at the same time its declination.
The third, its power of penetrating through gold, glass, stone, everything. The
fourth, its power of communicating its virtue from stone to iron, and from iron
to iron, without communication of substance. In this place, however, I am
speaking only of the first of these virtues — that is, its attractive power.
Remarkable also is the motion of attraction between quicksilver and gold,
insomuch that gold attracts quicksilver, though made up into ointments; and men
who work amid the vapors of quicksilver usually hold a piece of gold in their
mouths to collect the exhalations which would otherwise penetrate into their
skulls and bones; by which also the piece of gold is presently turned white. And
so much for the motion of the lesser congregation. Let the ninth motion be the magnetic, which, though it be of the same
genus with the motion of the lesser congregation, yet if it operates at great
distances and on large masses, deserves a separate investigation, especially if
it begin not with contact, as most, nor lead to contact, as all motions of
congregation do, but simply raises bodies or makes them swell, and nothing more.
For if the moon raises the waters, or makes moist things swell; if the starry
heaven attracts planets to their apogees; if the sun holds Venus and Mercury so
that their elongations never exceed a certain distance; these motions seem to
fall properly neither under the greater nor the lesser congregation, but to be
of a sort of intermediate and imperfect congregation, and therefore ought to
constitute a species by themselves. Let the tenth motion be that of flight (a motion the exact opposite of
that of the lesser congregation), by which bodies from antipathy flee from and
put to flight hostile bodies, and separate themselves from them or refuse to
mingle with them. For although in some cases this motion may seem to be an
accident or a consequence of the motion of the lesser congregation, because the
homogeneous parts cannot meet without dislodging and ejecting the heterogeneous,
still it is a motion that should be classed by itself and formed into a distinct
species, because in many cases the appetite of flight is seen to be more
dominant than the appetite of union. This motion is eminently conspicuous in the excretions of animals and not
less in objects odious to some of the senses, especially the smell and the
taste. For a fetid odor is so rejected by the sense of smell as to induce by
consent in the mouth of the stomach a motion of expulsion; a rough and bitter
taste is so rejected by the palate or throat as to induce by consent a shaking
of the head and a shudder. But this motion has place in other things also. It is
observed in certain forms of reaction; as in the middle region of the air, where
the cold seems to be the effect of the rejection of the nature of cold from the
confines of the heavenly bodies; as also the great heats and burnings which are
found in subterranean places appear to be rejections of the nature of heat from
the inner parts of the earth. For heat and cold, in small quantities, kill one
another. But if they be in large masses, and as it were in regular armies, the
result of the conflict is that they displace and eject each other in turn. It is
also said that cinnamon and other perfumes retain their scent longer when placed
near sinks and foul-smelling places because they refuse to come out and mingle
with stenches. It is certain that quicksilver, which of itself would reunite
into an entire mass, is kept from doing so by spittle, hog's lard, turpentine,
and the like, owing to the ill consent which its parts have with such bodies,
from which, when spread around them, they draw back, so that their desire to fly
from these intervening bodies is more powerful than their desire of uniting with
parts like themselves. And this is called the mortification of
quicksilver. The fact also that oil does not mix with water is not simply owing
to the difference of weight, but to the ill consent of these fluids, as may be
seen from the fact that spirit of wine, though lighter than oil, yet mixes well
enough with water. But most of all is the motion of flight conspicuous in niter
and such like crude bodies, which abhor flame; as in gunpowder, quicksilver, and
gold. But the flight of iron from one pole of the magnet is well observed by
Gilbert to be not a flight strictly speaking, but a conformity and meeting in a
more convenient situation. Let the eleventh motion be that of assimilation, or of
self-multiplication, or again of simple generation. By which I mean
not the generation of integral bodies, as plants or animals, but of bodies of
uniform texture. That is to say, by this motion such bodies convert others which
are related, or at any rate well disposed to them, into their own substance and
nature. Thus flame over vapors and oily substances multiplies itself and
generates new flame; air over water and watery substances multiplies itself and
generates new air; spirit, vegetable and animal, over the finer parts as well of
watery as of oily substance in its food, multiplies itself and generates new
spirit; the solid parts of plants and animals, as the leaf, flower, flesh, bone,
and the like, severally assimilate new substance to follow and supply what is
lost out of the juices of their food. For let no one adopt the wild fancy of
Paracelsus who (blinded I suppose by his distillations) will have it that
nutrition is caused only by separation, and that in bread and meat lie eye,
nose, brain, liver; in the moisture of the ground, root, leaf, and flower. For
as the artist out of the rude mass of stone or wood educes, by separation and
rejection of what is superfluous, leaf, flower, eye, nose, hand, foot, and the
like, so, he maintains, does Archæus, the internal artist, educe out of food by
separation and rejection the several members and parts of our body. But to leave
such trifles, it is most certain that the several parts, as well similar as
organic, in vegetables and animals do first attract with some degree of
selection the juices of their food, which are alike or nearly so for all, and
then assimilate them and turn them into their own nature. Nor does this
assimilation or simple generation take place only in animate bodies, but
inanimate also participate therein, as has been stated of flame and air.
Moreover, the non-vital spirit, which is contained in every tangible animated
substance, is constantly at work to digest the coarser parts and turn them into
spirit, to be afterwards discharged; whence ensues diminution of weight and
desiccation, as I have stated elsewhere. Nor must we set apart from assimilation
that accretion which is commonly distinguished from alimentation; as when clay
between stones concretes and turns into a stony substance, or the scaly
substance on the teeth turns into a substance as hard as the teeth themselves,
and so on. For I am of opinion that there resides in all bodies a desire for
assimilation as well as for uniting with homogeneous substances; but this virtue
is bound, as is the other, though not by the same means. But these means, as
well as the way of escape from them, ought to be investigated with all diligence
because they pertain to the rekindling of the vital power in old age. Lastly, it
seems worthy of observation that in the nine motions of which I have spoken
1 bodies seem to desire only the preservation of their nature, but in this
tenth the propagation of it. Let the twelfth motion be that of excitation, a motion which seems to
belong to the genus of assimilation and which I sometimes call by that name. For
it is a motion diffusive, communicative, transitive, and multiplicative, as is
the other, and agreeing with it generally in effect though differing in the mode
of effecting and in the subject matter. For the motion of assimilation proceeds,
as it were, with authority and command; it orders and forces the assimilated
body to turn into the assimilating. But the motion of excitation proceeds, so to
speak, with art and by insinuation, and stealthily, simply inviting and
disposing the excited body to the nature of the exciting. Again, the motion of
assimilation multiplies and transforms bodies and substances. Thus more flame is
produced, more air, more spirit, more flesh. But in the motion of excitation
virtues only are multiplied and transferred; more heat being engendered, more
magnetic power, more putrefying. This motion is particularly conspicuous in heat
and cold. For heat does not diffuse itself, in heating a body, by communication
of the original heat but simply by exciting the parts of the body to that motion
which is the form of heat, of which I have spoken in the First Vintage
concerning the nature of heat. Consequently heat is excited far more slowly and
with far greater difficulty in stone or metal than in air, owing to the
unfitness and unreadiness of those bodies to receive the motion. So that it is
probable that there may exist materials in the bowels of the earth which
altogether refuse to be heated, because through their greater condensation they
are destitute of that spirit with which this motion of excitation generally
begins. In like manner the magnet endues iron with a new disposition of its
parts and a conformable motion, but loses nothing of its own virtue. Similarly
leaven, yeast, curd, and certain poisons excite and invite a successive and
continued motion in dough, beer, cheese, or the human body, not so much by the
force of the exciting as by the predisposition and easy yielding of the excited
body. Let the thirteenth motion be the motion of impression, which also is
of the same genus with the motion of assimilation, and is of diffusive motions
the most subtle. I have thought fit, however, to make a distinct species of it,
on account of a remarkable difference between it and the two former. For the
simple motion of assimilation actually transforms the bodies themselves, so that
you may take away the first mover, and there will be no difference in what
follows. For the first kindling into flame, or the first turning into air, has
no effect on the flame or air next generated. In like manner, the motion of
excitation continues, after the first mover is withdrawn, for a very
considerable time: as in a heated body when the primary heat has been removed;
in magnetized iron when the magnet has been put away; in dough when the leaven
has been taken out. But the motion of impression, though diffusive and
transitive, seems to depend forever on the prime mover. So that if that be taken
away or cease to act, it immediately fails and comes to an end, and therefore
the effect must be produced in a moment, or at any rate in a very brief space of
time. The motions therefore of assimilation and excitation I call motions of the
generation of Jupiter, because the generation continues; but this, the
motion of the generation of Saturn, because the birth is immediately
devoured and absorbed. It manifests itself in three things: in rays of light, in
the percussions of sounds, and in magnetism, as regards the communication of the
influence. For if you take away light, colors and its other images instantly
disappear; if you take away the original percussion and the vibration of the
body thence produced, the sound soon after dies away. For though sounds are
troubled as they pass through their medium by winds, as if by waves, yet it must
be carefully noted that the original sound does not last all the time the
resonance goes on. For if you strike a bell, the sound seems to be continued for
a good long time, whereby we might easily be led into the error of supposing
that during the whole of the time the sound is, as it were, floating and hanging
in the air, which is quite untrue. For the resonance is not the identical sound,
but a renewal of it, as is shown by quieting or stopping the body struck. For if
the bell be held tight so that it cannot move, the sound at once comes to an end
and resounds no more — as in stringed instruments, if after the first percussion
the string be touched, either with the finger, as in the harp, or with the
quill, as in the spinet, the resonance immediately ceases. Again, when the
magnet is removed, the iron immediately drops. The moon indeed cannot be removed
from the sea, nor the earth from the falling body, and therefore we can try no
experiment in these cases; but the principle is the same. Let the fourteenth motion be the motion of configuration or
position, by which bodies seem to desire not union or separation, but
position, collocation, and configuration with respect to others. This motion is
a very abstruse one and has not been well investigated. In some cases, indeed,
it seems to be without a cause, though not, I believe, really so. For if it be
asked why the heavens revolve rather from east to west than from west to east,
or why they turn on poles placed near the Bears rather than about Orion, or in
any other part of heaven, such questions seem to border on insanity, since these
phenomena ought rather to be received as results of observation, and merely
positive facts. But though there are no doubt in nature certain things ultimate
and without cause, this does not appear to me to be one of them, being caused in
my opinion by a certain harmony and consent of the universe which has not yet
fallen under observation. And if we admit the motion of the earth from west to
east, the same questions remain. For it also moves on certain poles. And why, it
might be asked, should these poles be placed where they are, rather than
anywhere else? Again the polarity, direction, and declination of the magnet are
referable to this motion. There are also found in bodies natural as well as
artificial, especially in solids, a certain collocation and position of parts,
and a kind of threads and fibers, which ought to be carefully investigated
since, until they are understood, these bodies cannot be conveniently managed or
controlled. But those eddyings in fluids, by which when pressed, before they can
free themselves, they relieve each other that they may all have a fair share of
the pressure, belong more properly to the motion of liberty. Let the fifteenth motion be the motion of transition, or motion
according to the passages, by which the virtues of bodies are more or less
impeded or promoted by their media, according to the nature of the body and of
the acting virtues, and also of the medium. For one medium suits light, another
sound, another heat and cold, another magnetic virtues, and so on. Let the sixteenth motion be the royal (as I call it) or political
motion, by which the predominant and commanding parts in any body curb, tame,
subdue, and regulate the other parts, and compel them to unite, separate, stand
still, move, and range themselves, not in accordance with their own desires, but
as may conduce to the well-being of the commanding part; so that there is a sort
of government and polity exerted by the ruling over the subject parts. This
motion is eminently conspicuous in the spirits of animals where, as long as it
is in vigor, it tempers all the motions of the other parts. It is found however
in other bodies in a lower degree; as I said of blood and urine, which are not
decomposed till the spirit which mixes and keeps together their parts be
discharged or quenched. Nor is this motion confined to spirits, though in most
bodies the spirits are masters owing to their rapid and penetrating motion. But
in bodies of greater density and not filled with a lively and quickening spirit
(such as there is in quicksilver and vitriol), the thicker parts are the
masters, so that unless this yoke and restraint be by some expedient shaken off,
there is very little hope of any new transformation of such bodies. But let no
one suppose that I am forgetful of the point at issue, because while this series
and distribution of motions tends to nothing else but the better investigation
of their predominancy by instances of strife, I now make mention of predominancy
among the motions themselves. For in describing this royal motion I am not
treating of the predominancy of motions or virtues, but of the predominancy of
parts in bodies; such being the predominancy which constitutes the peculiar
species of motion in question. Let the seventeenth motion be the spontaneous motion of rotation, by
which bodies delighting in motion and favorably placed for it enjoy their own
nature, and follow themselves, not another body, and court (so to speak) their
own embraces. For bodies seem either to move without limit, or to remain
altogether at rest, or to tend to a limit at which, according to their nature,
they either revolve or rest. Those which are favorably placed, if they delight
in motion, move in a circle, with a motion, that is, eternal and infinite. Those
which are favorably placed, and abhor motion, remain at rest. Those which are
not favorably placed move in a right line (as the shortest path) to consort with
bodies of their own nature. But this motion of rotation admits of nine
differences regarding 1. the center round which the bodies move; 2. the poles on
which they move; 3. their circumference or orbit, according to their distance
from the center; 4. their velocity, according to the greater or less rapidity of
their rotation; 5. the course of their motion, as from east to west, or from
west to east; 6. their declination from a perfect circle by spiral lines more or
less distant from their center; 7. their declination from a perfect circle by
spiral lines more or less distant from their poles; 8. the greater or lesser
distance of these spirals from each other; 9. and lastly, the variation of the
poles themselves, if they be movable; which, however, has nothing to do with
rotation unless it be circular. This motion in common and long received opinion
is looked upon as the proper motion of heavenly bodies, though there is a grave
dispute with regard to it among some both of the ancients and of the moderns,
who have attributed rotation to the earth. But a juster question perhaps arises
upon this (if it be not past question), namely, whether this motion (admitting
that the earth stands still) is confined to the heavens, and does not rather
descend and communicate itself to the air and waters. The motion of rotation in
missiles, as in darts, arrows, musket balls, and the like, I refer to the motion
of liberty. Let the eighteenth motion be the motion of trepidation, to which, as
understood by astronomers, I do not attach much credit. But in searching
carefully everywhere for the appetites of natural bodies this motion comes
before us and ought, it seems, to constitute a species by itself. It is a motion
of what may be called perpetual captivity and occurs when bodies that have not
quite found their right place, and yet are not altogether uneasy, keep forever
trembling and stirring themselves restlessly, neither content as they are nor
daring to advance further. Such a motion is found in the heart and pulses of
animals, and must of necessity occur in all bodies which so exist in a mean
state between conveniences and inconveniences that when disturbed they strive to
free themselves, and being again repulsed, are yet forever trying again. Let the nineteenth and last motion be one which, though it hardly answers to
the name, is yet indisputably a motion; and let us call it the motion of
repose, or of aversion to move. It is by this motion that the earth
stands still in its mass while its extremities are moving toward the middle —
not to an imaginary center, but to union. By this appetite also all bodies of
considerable density abhor motion. Indeed, the desire of not moving is the only
appetite they have; and though in countless ways they be enticed and challenged
to motion, they yet, as far as they can, maintain their proper nature. And if
compelled to move, they nevertheless seem always intent on recovering their
state of rest and moving no more. While thus engaged, indeed, they show
themselves active and struggle for it with agility and swiftness enough, as
weary and impatient of all delay. Of this appetite but a partial representation
can be seen, since here with us, from the subduing and concocting power of the
heavenly bodies, all tangible substances are not only not condensed to their
utmost, but are even mixed with some portion of spirit. Thus, then, have I set forth the species or simple elements of motions,
appetites, and active virtues, which are in nature most general. And under these
heads no small portion of natural science is sketched out. I do not, however,
mean to say that other species may not be added, or that the divisions I have
made may not be drawn more accurately according to the true veins of nature, or
reduced to a smaller number. Observe, nevertheless, that I am not here speaking
of any abstract divisions, as if one were to say that bodies desire either the
exaltation or the propagation or the fruition of their nature; or again, that
the motions of things tend to the preservation and good either of the universe,
as resistance and connection; or of great wholes, as the motions of the greater
congregation, rotation, and aversion to move; or of special forms, as the rest.
For though these assertions be true, yet unless they be defined by true lines in
matter and the fabric of nature, they are speculative and of little use.
Meanwhile, these will suffice and be of good service in weighing the
predominancies of virtues and finding out instances of strife, which is our
present object For of the motions I have set forth some are quite invincible; some are
stronger than others, fettering, curbing, arranging them; some carry farther
than others; some outstrip others in speed; some cherish, strengthen, enlarge,
and accelerate others. The motion of resistance is altogether adamantine and invincible. Whether the
motion of connection be so, I am still undecided. For I am not prepared to say
for certain whether or no there be a vacuum, either collected in one place or
interspersed in the pores of bodies. But of one thing I am satisfied, that the
reason for which a vacuum was introduced by Leucippus and Democritus (namely,
that without it the same bodies could not embrace and fill sometimes larger and
sometimes smaller spaces) is a false one. For matter is clearly capable of
folding and unfolding itself in space, within certain limits, without the
interposition of a vacuum; nor is there in air two thousand times as much of
vacuity as there is in gold. which on their hypothesis there should be. Of this
I am sufficiently convinced by the potency of the virtues of pneumatical bodies
(which otherwise would be floating in empty space like fine dust) and by many
other proofs. As for the other motions, they rule and are ruled in turn, in
proportion to their vigor, quantity, velocity, force of projection, and also to
the helps and hindrances they meet with. For instance, there are some armed magnets that hold and suspend iron of
sixty times their own weight, so far does the motion of the lesser prevail over
the motion of the greater congregation; but if the weight be increased, it is
overcome. A lever of given strength will raise a given weight, so far does the
motion of liberty prevail over that of the greater congregation; but if the
weight be increased, it is overcome. Leather stretches to a certain extent
without breaking, so far does the motion of continuity prevail over the motion
of tension; but if the tension be increased, the leather breaks and the motion
of continuity is overcome. Water runs out at a crack of a certain size, so far
does the motion of the greater congregation prevail over the motion of
continuity; but if the crack be smaller, it gives way, and the motion of
continuity prevails. If you charge a gun with ball and sulphur only, and apply
the match, the ball is not discharged, the motion of the greater congregation
overcoming in this case the motion of matter. But if you charge with gunpowder,
the motion of matter in the sulphur prevails, being aided by the motions of
matter and of flight in the niter. And so of other cases. Instances of strife,
therefore, which point out the predominancies of virtues together with the
manner and proportion in which they predominate or give place, should be sought
and collected from all quarters with keen and careful diligence. Nor should we examine less carefully the modes in which these motions give
way. That is to say, whether they stop altogether or whether they continue to
resist but are overpowered. For in bodies here with us there is no real rest,
either in wholes or in parts, but only in appearance. And this apparent rest is
caused either by equilibrium, or by absolute predominancy of motions: by
equilibrium, as in scales, which stand still if the weights be equal; by
predominancy, as in watering pots with holes in them, where the water rests and
is kept from falling out by the predominancy of the motion of connection. But it
should be observed, as I have said, how far these yielding motions carry their
resistance. For if a man be pinned to the ground, tied hand and foot, or
otherwise held fast, and yet struggle to rise with all his might, the resistance
is not the less though it be unsuccessful. But the real state of the case (I
mean whether by predominancy the yielding motion is, so to speak, annihilated,
or rather whether a resistance is continued, though we cannot see it) will
perhaps, though latent in the conflicts of motions, be apparent in their
concurrence. For example, let trial be made in shooting. See how far a gun will
carry a ball straight, or as they say point-blank, and then try whether, if it
be fired upward, the stroke will be feebler than when it is fired downward,
where the motion of gravity concurs with the blow. Lastly, such canons of predominance as we meet with should be collected; for
instance, that the more common the good sought, the stronger the motion. Thus
the motion of connection, which regards communion with the universe, is stronger
than the motion of gravity, which regards only communion with dense bodies.
Again, that appetites which aim at a private good seldom prevail against
appetites which aim at a more public good, except in small quantities — rules
which I wish held good in politics. 1 [which relate to concrete bodies rather than to matter in
general —? Ed.] XLIX Among Prerogative Instances I will put in the twenty-fifth place
intimating instances, those, I mean, which intimate or point out what is
useful to man. For mere power and mere knowledge exalt human nature, but do not
bless it. We must therefore gather from the whole store of things such as make
most for the uses of life. But a more proper place for speaking of these will be
when I come to treat of applications to practice. Besides, in the work itself of
interpretation in each particular subject, I always assign a place to the
human chart, or chart of things to be wished for. For to form
judicious wishes is as much a part of knowledge as to ask judicious questions. L Among Prerogative Instances I will put in the twenty-sixth place
Polychrest Instances, or Instances of General Use. They are those
which relate to a variety of cases and occur frequently and therefore save no
small amount of labor and fresh demonstration. Of the instruments and
contrivances themselves the proper place for speaking will be when I come to
speak of applications to practice and modes of experimenting. Moreover, those
which have been already discovered and come into use will be described in the
particular histories of the several arts. At present I will subjoin a few
general remarks on them as examples merely of this general use. Besides the simple bringing together and putting asunder of them, man
operates upon natural bodies chiefly in seven ways, viz., either by exclusion of
whatever impedes and disturbs; or by compressions, extensions, agitations, and
the like; or by heat and cold; or by continuance in a suitable place; or by the
checking and regulation of motion; or by special sympathies; or by the
seasonable and proper alternation, series, and succession of all these ways, or
at any rate of some of them. With regard to the first, the common air, which is everywhere about us and
pressing in, and the rays of the heavenly bodies, cause much disturbance.
Whatever therefore serves to exclude them may justly be reckoned among things of
general use. To this head belong the material and thickness of the vessels in
which the bodies are placed on which we are going to operate; also the perfect
stopping up of vessels by consolidation and lutum sapientiæ, as the
chemists call it. Also the closing in of substances by liquids poured on the
outside is a thing of very great use, as when they pour oil on wine or juices of
herbs, which spreading over the surface like a lid preserves them excellently
from the injury of the air. Nor are powders bad things; for though they contain
air mixed up with them, they yet repel the force of the body of air round about,
as we see in the preservation of grapes and other fruits in sand and flour. It
is good too to spread bodies over with wax, honey, pitch, and like tenacious
substances, for the more perfect enclosure of them and to keep off the air and
heavenly bodies. I have sometimes tried the effect of laying up a vessel or some
other body in quicksilver, which of all substances that can be poured round
another is far the densest. Caverns, again, and subterraneous pits are of great
use in keeping off the heat of the sun and that open air which preys upon
bodies, and such are used in the north of Germany as granaries. The sinking of
bodies in water has likewise the same effect, as I remember to have heard of
bottles of wine being let down into a deep well to cool, but through accident or
neglect being left there for many years, and then taken out; and that the wine
not only was free from sourness or flatness, but tasted much finer, owing, it
would seem, to a more exquisite commixture of its parts. And if the case require
that bodies be let down to the bottom of the water, as in a river or the sea,
without either touching the water or being enclosed in stopped vessels, but
surrounded by air alone, there is good use in the vessel which has been
sometimes employed for working under water on sunk ships whereby divers are
enabled to remain a long while below, and take breath from time to time. This
machine was a hollow bell made of metal which, being let down parallel to the
surface of the water, carried with it to the bottom all the air it contained. It
stood on three feet (like a tripod) the height of which was somewhat less than
that of a man, so that the diver, when his breath failed, could put his head
into the hollow of the bell, take breath, and then go on with his work. I have
heard also of a sort of machine or boat capable of carrying men under water for
some distance. Be that as it may, under such a vessel as I have described bodies
of any sort can easily be suspended, and it is on that account that I have
mentioned this experiment. There is also another advantage in the careful and complete closing of
bodies. For not only does it keep the outer air from getting in (of which I have
already spoken), but also it keeps the spirit of the body, on which the
operation is going on inside, from getting out. For it is necessary for one who
operates on natural bodies to be certain of his total quantities, that is, that
nothing evaporates or flows away. For then and then only are profound
alterations made in bodies when, while nature prevents annihilation, art
prevents also the loss or escape of any part. On this subject there has
prevailed a false opinion which, if true, would make us well nigh despair of
preserving the perfect quantity without diminution, namely, that the spirits of
bodies, and air when rarefied by a high degree of heat, cannot be contained in
closed vessels but escape through their more delicate pores. To this opinion men
have been led by common experiment of an inverted cup placed on water with a
candle in it or a piece of paper lighted; the consequence of which is that the
water is drawn up; and also by the similar experiment of cupping glasses which
when heated over flame draw up the flesh. For in each of these experiments they
imagine that the rarefied air escapes, and that its quantity being thereby
diminished, the water or flesh comes up into its place by the motion of
connection. But this is altogether a mistake. For the air is not diminished in
quantity, but contracted in space; nor does the motion of the rising of the
water commence till the flame is extinguished or the air cooled. And therefore
physicians, to make their cupping glasses draw better, lay on them cold sponges
dipped in water. And therefore there is no reason why men should be much afraid
of the easy escape of air or spirits. For though it be true that the most solid
bodies have pores, still air or spirit do not easily submit to such extremely
fine comminution, just as water refuses to run out at very small chinks. With regard to the second of the seven modes of operating above mentioned, it
is particularly to be observed that compression and such violent means have
indeed, with respect to local motion and the like, a most powerful effect, as in
machines and projectiles, an effect which even causes the destruction of organic
bodies and of such virtues as consist altogether in motion. For all life, nay
all flame and ignition, is destroyed by compression, just as every machine is
spoiled or deranged by the same. It causes the destruction likewise of virtues
which consist in the position and coarser dissimilarity of parts. This is the
case with colors, for the whole flower has not the same color as when it is
bruised, nor the whole piece of amber as the same piece pulverized. So also it
is with tastes. For there is not the same taste in an unripe pear as there is in
a squeezed and softened one, for it manifestly contracts sweetness by the
process. But for the more remarkable transformations and alterations of bodies
of uniform structure such violent means are of little avail, since bodies do not
acquire thereby a new consistency that is constant and quiescent, but one that
is transitory and ever striving to recover and liberate itself. It would not be
amiss, however, to make some careful experiments for the purpose of ascertaining
whether the condensation or the rarefaction of a body of nearly uniform
structure (as air, water, oil, and the like), being induced by violence, can be
made to be constant and fixed, and to become a kind of nature. This should first
be tried by simple continuance, and then by means of helps and consents. And the
trial might easily have been made (if it had but occurred to me) when I was
condensing water, as mentioned above, by hammer and press, till it burst forth
from its enclosure. For I should have left the flattened sphere to itself for a
few days, and after that drawn off the water, that so I might have seen whether
it would immediately occupy the same dimensions which it had before
condensation. If it had not done so, either immediately or at any rate soon
after, we might have pronounced the condensation a constant one; if it had, it
would have appeared that a restoration had taken place and that the compression
was transitory. Something of a similar kind I might have tried also with the
expansion of air in the glass eggs. For after powerful suction I might have
stopped them suddenly and tightly; I might have left the eggs so stopped for
some days and then tried whether on opening the hole the air would be drawn up
with a hissing noise, or whether on plunging them into water, as much water
would be drawn up as there would have been at first without the delay. For it is
probable — at least it is worth trying — that this might have been, and may be,
the case; since in bodies of structure not quite so uniform the lapse of time
does produce such effects. For a stick bent for some time by compression does
not recoil, and this must not be imputed to any loss of quantity in the wood
through the lapse of time, since the same will be the case with a plate of steel
if the time be increased, and steel does not evaporate. But if the experiment
succeed not with mere continuance, the business must not be abandoned, but other
aids must be employed. For it is no small gain if by the application of violence
we can communicate to bodies fixed and permanent natures. For thus air can be
turned into water by condensation, and many other effects of the kind can be
produced, man being more the master of violent motions than of the rest. The third of the seven modes above-mentioned relates to that which, whether
in nature or in art, is the great instrument of operation, viz., heat and cold.
And herein man's power is clearly lame on one side. For we have the heat of fire
which is infinitely more potent and intense than the heat of the sun as it
reaches us, or the warmth of animals. But we have no cold save such as is to be
got in wintertime, or in caverns, or by application of snow and ice, which is
about as much perhaps in comparison as the heat of the sun at noon in the torrid
zone, increased by the reflections of mountains and walls. For such heat as well
as such cold can be endured by animals for a short time. But they are nothing to
be compared to the heat of a burning furnace, or with any cold corresponding to
it in intensity. Thus all things with us tend to rarefaction, and desiccation,
and consumption; nothing hardly to condensation and inteneration except by
mixtures and methods that may be called spurious. Instances of cold therefore
should be collected with all diligence. And such it seems may be found by
exposing bodies on steeples in sharp frosts; by laying them in subterranean
caverns; by surrounding them with snow and ice in deep pits dug for the purpose;
by letting them down into wells; by burying them in quicksilver and metals; by
plunging them into waters which petrify wood; by burying them in the earth, as
the Chinese are said to do in the making of porcelain, where masses made for the
purpose are left, we are told, underground for forty or fifty years, and
transmitted to heirs, as a kind of artificial minerals; and by similar
processes. And so too all natural condensations caused by cold should be
investigated, in order that, their causes being known, they may be imitated by
art. Such we see in the sweating of marble and stones; in the dews condensed on
the inside of windowpanes toward morning after a night's frost; in the formation
and gathering of vapors into water under the earth, from which springs often
bubble up. Everything of this kind should be collected. Besides things which are cold to the touch, there are found others having the
power of cold, which also condense, but which seem to act on the bodies of
animals only, and hardly on others. Of this sort we have many instances in
medicines and plasters, some of which condense the flesh and tangible parts, as
astringent and inspissatory medicaments; while others condense the spirits, as
is most observable in soporifics. There are two ways in which spirits are
condensed by medicaments soporific, or provocative of sleep: one by quieting
their motion, the other by putting them to flight. Thus violets, dried rose
leaves, lettuce, and like benedict or benignant medicaments, by their kindly and
gently cooling fumes invite the spirits to unite and quiet their eager and
restless motion. Rose water, too, applied to the nose in a fainting fit, causes
the resolved and too relaxed spirits to recover themselves and, as it were,
cherishes them. But opiates and kindred medicaments put the spirits utterly to
flight by their malignant and hostile nature. And therefore if they be applied
to an external part, the spirits immediately flee away from that part and do not
readily flow into it again; if taken internally, their fumes, ascending to the
head, disperse in all directions the spirits contained in the ventricles of the
brain; and these spirits thus withdrawing themselves, and unable to escape into
any other part, are by consequence brought together and condensed, and sometimes
are utterly choked and extinguished; though on the other hand these same opiates
taken in moderation do by a secondary accident (namely, the condensation which
succeeds the coming together) comfort the spirits and render them more robust,
and check their useless and inflammatory motions; whereby they contribute no
little to the cure of diseases and prolongation of life. Nor should we omit the means of preparing bodies to receive cold. Among
others I may mention that water slightly warm is more easily frozen than quite
cold. Besides, since nature supplies cold as sparingly, we must do as the
apothecaries do who, when they cannot get a simple, take its succedaneum or
quid pro quo, as they call it — such as aloes for balsam, cassia for
cinnamon. In like manner we should look round carefully to see if there be
anything that will do instead of cold, that is to say, any means by which
condensations can be effected in bodies otherwise than by cold, the proper
office of which is to effect them. Such condensations, as far as yet appears,
would seem to be limited to four. The first of these is caused by simple
compression, which can do but little for permanent density, since bodies recoil,
but which perhaps may be of use as an auxiliary. The second is caused by the
contraction of the coarser parts in a body after the escape of the finer, such
as takes place in indurations by fire, in the repeated quenchings of metals, and
like processes. The third is caused by the coming together of those homogeneous
parts in a body which are the most solid, and which previously had been
dispersed and mixed with the less solid; as in the restoration of sublimated
mercury, which occupies a far greater space in powder than as simple mercury,
and similarly in all purging of metals from their dross. The fourth is brought
about through sympathy, by applying substances which from some occult power
condense. These sympathies or consents at present manifest themselves but
rarely, which is no wonder, since before we succeed in discovering forms and
configurations we cannot hope for much from an inquiry into sympathies. With
regard to the bodies of animals, indeed, there is no doubt that there are many
medicines, whether taken internally or externally, which condense as it were by
consent, as I have stated a little above. But in the case of inanimate
substances such operation is rare. There has indeed been spread abroad, as well
in books as in common rumor, the story of a tree in one of the Tercera or Canary
Isles (I do not well remember which) which is constantly dripping, so as to some
extent to supply the inhabitants with water. And Paracelsus says that the herb
called Ros Solis is at noon and under a burning sun filled with dew,
while all the other herbs round it are dry. But both of these stories I look
upon as fabulous. If they were true, such instances would be of most signal use
and most worthy of examination. Nor do I conceive that those honeydews, like
manna, which are found on the leaves of the oak in the month of May, are formed
and condensed by any peculiar property in the leaf of the oak, but while they
fall equally on all leaves, they are retained on those of the oak as being well
united and not spongy as most of the others are. As regards heat, man indeed has abundant store and command thereof, but
observation and investigation are wanting in some particulars, and those the
most necessary, let the alchemists say what they will. For the effects of
intense heat are sought for and brought into view, but those of a gentler heat,
which fall in most with the ways of nature, are not explored and therefore are
unknown. And therefore we see that by the heats generally used the spirits of
bodies are greatly exalted, as in strong waters and other chemical oils; that
the tangible parts are hardened and, the volatile being discharged, sometimes
fixed; that the homogeneous parts are separated, while the heterogeneous are in
a coarse way incorporated and mixed up together; above all, that the junctures
of composite bodies and their more subtle configurations are broken up and
confounded. Whereas the operations of a gentler heat ought to have been tried
and explored, whereby more subtle mixtures and regular configurations might be
generated and educed, after the model of nature and in imitation of the works of
the sun — as I have shadowed forth in the Aphorism on Instances of Alliance. For
the operations of nature are performed by far smaller portions at a time, and by
arrangements far more exquisite and varied than the operations of fire, as we
use it now. And it is then that we shall see a real increase in the power of man
when by artificial heats and other agencies the works of nature can be
represented in form, perfected in virtue, varied in quantity, and, I may add,
accelerated in time. For the rust of iron is slow in forming, but the turning
into Crocus Martis is immediate; and it is the same with verdigris and
ceruse; crystal is produced by a long process, while glass is blown at once;
stones take a long time to grow, while bricks are quickly baked. Meanwhile (to
come to our present business), heats of every kind, with their effects, should
be diligently collected from all quarters and investigated — the heat of
heavenly bodies by their rays direct, reflected, refracted, and united in
burning glasses and mirrors; the heat of lightning, of flame, of coal fire; of
fire from different materials; of fire close and open, straitened and in full
flow, modified in fine by the different structures of furnaces; of fire excited
by blowing; of fire quiescent and not excited; of fire removed to a greater or
less distance; of fire passing through various media; moist heats, as of a
vessel floating in hot water, of dung, of external and internal animal warmth,
of confined hay; dry heats, as of ashes, lime, warm sand; in short, heats of all
kinds with their degrees. But above all we must try to investigate and discover the effects and
operations of heat when applied and withdrawn gradually, orderly, and
periodically, at due distances and for due times. For such orderly inequality is
in truth the daughter of the heavens and mother of generation; nor is anything
great to be expected from a heat either vehement or precipitate or that comes by
fits and starts. In vegetables this is most manifest; and also in the wombs of
animals there is a great inequality of heat, from the motion, sleep, food, and
passions of the female in gestation. Lastly, in the wombs of the earth itself,
those I mean in which metals and fossils are formed, the same inequality has
place and force. Which makes the unskillfulness of some alchemists of the
reformed school all the more remarkable — who have conceived that by the equable
warmth of lamps and the like, burning uniformly, they can attain their end. And
so much for the operations and effects of heat. To examine them thoroughly would
be premature, till the forms of things and the configurations of bodies have
been further investigated and brought to light. For it will then be time to
seek, apply, and adapt our instruments when we are clear as to the pattern. The fourth mode of operating is by continuance, which is as it were the
steward and almoner of nature. Continuance I call it when a body is left to
itself for a considerable time, being meanwhile defended from all external
force. For then only do the internal motions exhibit and perfect themselves when
the extraneous and adventitious are stopped. Now the works of time are far
subtler than those of fire. For wine cannot be so clarified by fire as it is by
time; nor are the ashes produced by fire so fine as the dust into which
substances are resolved and wasted by ages. So too the sudden incorporations and
mixtures precipitated by fire are far inferior to those which are brought about
by time. And the dissimilar and varied configurations which bodies by
continuance put on, such as putrefactions, are destroyed by fire or any violent
heat. Meanwhile it would not be out of place to observe that the motions of
bodies when quite shut up have in them something of violence. For such
imprisonment impedes the spontaneous motions of the body. And therefore
continuance in an open vessel is best for separations; in a vessel quite closed
for commixtures; in a vessel partly closed, but with the air entering, for
putrefactions. But, indeed, instances showing the effects and operations of
continuance should be carefully collected from all quarters. The regulation of motion (which is the fifth mode of operating) is of no
little service. I call it regulation of motion when one body meeting another
impedes, repels, admits or directs its spontaneous motion. It consists for the
most part in the shape and position of vessels. Thus the upright cone in
alembics helps the condensation of vapors; the inverted cone in receivers helps
the draining off of the dregs of sugar. Sometimes a winding form is required,
and one that narrows and widens in turn, and the like. For all percolation
depends on this, that the meeting body opens the way to one portion of the body
met and shuts it to another. Nor is the business of percolation or other
regulation of motion always performed from without. It may also be done by a
body within a body, as when stones are dropped into water to collect the earthy
parts; or when syrups are clarified with the whites of eggs that the coarser
parts may adhere thereto, after which they may be removed. It is also to this
regulation of motion that Telesius has rashly and ignorantly enough attributed
the shapes of animals, which he says are owing to the channels and folds in the
womb. But he should have been able to show the like formation in the shells of
eggs, in which there are no wrinkles or inequalities. It is true, however, that
the regulation of motion gives the shapes in molding and casting. Operations by consents or aversions (which is the sixth mode) often lie
deeply hid. For what are called occult and specific properties, or sympathies
and antipathies, are in great part corruptions of philosophy. Nor can we have
much hope of discovering the consents of things before the discovery of forms
and simple configurations. For consent is nothing else than the adaptation of
forms and configurations to each other. The broader and more general consents of things are not, however, quite so
obscure. I will therefore begin with them. Their first and chief diversity is
this, that some bodies differ widely as to density and rarity but agree in
configurations, while others agree as to density and rarity but differ in
configurations. For it has not been ill observed by the chemists in their triad
of first principles that sulphur and mercury run through the whole universe.
(For what they add about salt is absurd, and introduced merely to take in bodies
earthy, dry, and fixed.) But certainly in these two one of the most general
consents in nature does seem to be observable. For there is consent between
sulphur, oil, and greasy exhalation, flame, and perhaps the body of a star. So
is there between mercury, water and watery vapors, air, and perhaps the pure and
intersidereal ether. Yet these two quaternions or great tribes of things (each
within its own limits) differ immensely in quantity of matter and density, but
agree very well in configuration; as appears in numerous cases. On the other
hand metals agree well together in quantity and density, especially as compared
with vegetables, etc., but differ very widely in configuration; while in like
manner vegetables and animals vary almost infinitely in their configurations,
but in quantity of matter or density their variation is confined to narrow
limits. The next most general consent is that between primary bodies and their
supports, that is, their menstrua and foods. We must therefore inquire, under
what climates, in what earth, and at what depth, the several metals are
generated; and so of gems, whether produced on rocks or in mines; also in what
soil the several trees and shrubs and herbs thrive best and take, so to speak,
most delight; moreover what manurings, whether by dung of any sort, or by chalk,
sea sand, ashes, etc., do the most good; and which of them are most suitable and
effective according to the varieties of soil. Again, the grafting and
inoculating of trees and plants, and the principle of it, that is to say, what
plants prosper best on what stocks, depends much on sympathy. Under this head it
would be an agreeable experiment, which I have heard has been lately tried, of
engrafting forest trees (a practice hitherto confined to fruit trees), whereby
the leaves and fruit are greatly enlarged and the trees made more shady. In like
manner the different foods of animals should be noted under general heads, and
with their negatives. For carnivorous animals cannot live on herbs, whence the
order of Feuillans (though the will in man has more power over the body than in
other animals) has after trial (they say) well nigh disappeared, the thing not
being endurable by human nature. Also the different materials of putrefaction,
whence animalculae are generated, should be observed. The consents of primary bodies with their subordinates (for such those may be
considered which I have noted) are sufficiently obvious. To these may be added
the consents of the senses with their objects. For these consents, since they
are most manifest and have been well observed and keenly sifted, may possibly
shed great light on other consents also which are latent. But the inner consents and aversions, or friendships and enmities, of bodies
(for I am almost weary of the words sympathy and antipathy on account of the
superstitions and vanities associated with them) are either falsely ascribed, or
mixed with fables, or from want of observation very rarely met with. For if it
be said that there is enmity between the vine and colewort, because when planted
near each other they do not thrive, the reason is obvious — that both of these
plants are succulent and exhaust the ground, and thus one robs the other. If it
be said that there is consent and friendship between corn and the corn cockle or
the wild poppy, because these herbs hardly come up except in ploughed fields, it
should rather be said that there is enmity between them, because the poppy and
corn cockle are emitted and generated from a juice of the earth which the corn
has left and rejected; so that sowing the ground with corn prepares it for their
growth. And of such false ascriptions there is a great number. As for fables,
they should be utterly exterminated. There remains indeed a scanty store of
consents which have been approved by sure experiment, such as those of the
magnet and iron, of gold and quicksilver, and the like. And in chemical
experiments on metals there are found also some others worthy of observation.
But they are found in greatest abundance (if one may speak of abundance in such
a scarcity) in certain medicines which by their occult (as they are called) and
specific properties have relation either to limbs, or humors, or diseases, or
sometimes to individual natures. Nor should we omit the consents between the
motions and changes of the moon and the affections of bodies below, such as may
be gathered and admitted, after strict and honest scrutiny, from experiments in
agriculture, navigation, medicine, and other sciences. But the rarer all the
instances of more secret consents are, the greater the diligence with which they
should be sought after, by means of faithful and honest traditions and
narrations; provided this be done without any levity or credulity, but with an
anxious and (so to speak) a doubting faith. There remains a consent of bodies,
inartificial perhaps in mode of operation, but in use a polychrest, which should
in no wise be omitted, but examined into with careful attention. I mean the
proneness or reluctance of bodies to draw together or unite by composition or
simple apposition. For some bodies are mixed together and incorporated easily,
but others with difficulty and reluctance. Thus powders mix best with water,
ashes and lime with oils, and so on. Nor should we merely collect instances of
the propensity or aversion of bodies for mixture, but also of the collocation of
their parts, of their distribution and digestion when they are mixed, and
finally of their predominancy after the mixture is completed. There remains the seventh and last of the seven modes of operation, namely,
the means of operating by the alternation of the former six. But it would not be
seasonable to bring forward examples of this till our search has been carried
somewhat more deeply into the others singly. Now a series or chain of such
alternations, adapted to particular effects, is a thing at once most difficult
to discover and most effective to work with. But men are utterly impatient both
of the inquiry and the practice, though it is the very thread of the labyrinth
as regards works of any magnitude. Let this suffice to exemplify the polychrest
instances. LI Among Prerogative Instances I will put in the twenty-seventh and last place
Instances of Magic, by which I mean those wherein the material or
efficient cause is scanty or small as compared with the work and effect
produced. So that even where they are common they seem like miracles; some at
first sight, others even after attentive consideration. These, indeed, nature of
herself supplies sparingly, but what she may do when her folds have been shaken
out, and after the discovery of forms and processes and configurations, time
will show. But these magical effects (according to my present conjecture) are
brought about in three ways: either by self-multiplication, as in fire, and in
poisons called specific, and also in motions which are increased in power by
passing from wheel to wheel; or by excitation or invitation in another body, as
in the magnet, which excites numberless needles without losing any of its
virtue, or in yeast and the like; or by anticipation of motion, as in the case
already mentioned of gunpowder and cannons and mines. Of which ways the two
former require a knowledge of consents, the third a knowledge of the measurement
of motions. Whether there be any mode of changing bodies per minima (as
they call it) and of transposing the subtler configurations of matter (a thing
required in every sort of transformation of bodies) so that art may be enabled
to do in a short time that which nature accomplishes by many windings, is a
point on which I have at present no sure indications. And as in matters solid
and true I aspire to the ultimate and supreme, so do I forever hate all things
vain and tumid, and do my best to discard them. LII So much then for the dignities or prerogatives of instances. It must be
remembered, however, that in this Organon of mine I am handling logic, not
philosophy. But since my logic aims to teach and instruct the understanding, not
that it may with the slender tendrils of the mind snatch at and lay hold of
abstract notions (as the common logic does), but that it may in very truth
dissect nature, and discover the virtues and actions of bodies, with their laws
as determined in matter; so that this science flows not merely from the nature
of the mind, but also from the nature of things — no wonder that it is
everywhere sprinkled and illustrated with speculations and experiments in
nature, as examples of the art I teach. It appears then from what has been said
that there are twenty-seven prerogative instances, namely, solitary instances;
migratory instances; striking instances; clandestine instances; constitutive
instances; conformable instances; singular instances; deviating instances;
bordering instances; instances of power; instances of companionship and of
enmity; subjunctive instances; instances of alliance; instances of the
fingerpost; instances of divorce; instances of the door; summoning instances;
instances of the road; instances supplementary; dissecting instances; instances
of the rod; instances of the course; doses of nature; instances of strife;
intimating instances; polychrest instances; magical instances. Now the use of
these instances, wherein they excel common instances, is found either in the
informative part or in the operative, or in both. As regards the informative,
they assist either the senses or the understanding: the senses, as the five
instances of the lamp; the understanding, either by hastening the exclusion of
the form, as solitary instances; or by narrowing and indicating more nearly the
affirmative of the form, as instances migratory, striking, of companionship, and
subjunctive; or by exalting the understanding and leading it to genera and
common natures, either immediately, as instances clandestine, singular, and of
alliance, or in the next degree, as constitutive, or in the lowest, as
conformable; or by setting the understanding right when led astray by habit, as
deviating instances; or by leading it to the great form or fabric of the
universe, as bordering instances; or by guarding it against false forms and
causes, as instances of the fingerpost and of divorce. In the operative part
they either point out, or measure, or facilitate practice. They point it out by
showing with what we should begin, that we may not go again over old ground, as
instances of power; or to what we should aspire if means be given, as intimating
instances. The four mathematical instances measure practice: polychrest and
magical instances facilitate it. Again, out of these twenty-seven instances there are some of which we must
make a collection at once, as I said above, without waiting for the particular
investigation of natures. Of this sort are instances conformable, singular,
deviating, bordering, of power, of the dose, intimating, polychrest, and
magical. For these either help and set right the understanding and senses, or
furnish practice with her tools in a general way. The rest need not be inquired
into till we come to make Tables of Presentation for the work of the interpreter
concerning some particular nature. For the instances marked and endowed with
these prerogatives are as a soul amid the common instances of presentation and,
as I said at first, a few of them do instead of many; and therefore in the
formation of the Tables they must be investigated with all zeal and set down
therein. It was necessary to handle them beforehand because I shall have to
speak of them in what follows. But now I must proceed to the supports and
rectifications of induction, and then to concretes, and Latent Processes, and
Latent Configurations, and the rest, as set forth in order in the twenty-first
Aphorism; that at length (like an honest and faithful guardian) I may hand over
to men their fortunes, now their understanding is emancipated and come as it
were of age; whence there cannot but follow an improvement in man's estate and
an enlargement of his power over nature. For man by the fall fell at the same
time from his state of innocency and from his dominion over creation. Both of
these losses however can even in this life be in some part repaired; the former
by religion and faith, the latter by arts and sciences. For creation was not by
the curse made altogether and forever a rebel, but in virtue of that charter "In
the sweat of thy face shall thou eat bread," it is now by various labors (not
certainly by disputations or idle magical ceremonies, but by various labors) at
length and in some measure subdued to the supplying of man with bread, that is,
to the uses of human life. RETURN TO KIMBALL FILES "Essays" | | | | | | | | | | |
Francis Bacon
Novum Organum
or
THE NEW ORGANON
or
TRUE DIRECTIONS CONCERNING THE INTERPRETATION OF NATURE
[SAC editor has introduced bold face to highlight passages of
greatest relevance to our course. You might want to jump directly to the famous
passages about "Idols" (false images that have
always so seriously distorted human thought). Here
are some of the thoughts of SAC editor on the
difficulties involved in Bacon's assault on "words" and on language in general]
First gave the seed whence waving harvests grow,
And re-created all our life below.