Nanowire Thermoelectrics
Thermoelectric materials generate electricity by extracting heat
from a heat gradient. The best commercially available thermoelectrics
have a figure of merit of ZT ~ 1, corresponding to an energy conversion
efficiency of about 10% of the Carnot value. Whereas this relatively
low efficiency limits thermoelectrics to niche applications, a significant
increase in efficiency would have substantial economic impact. For
instance, an effective thermoelectric may be used to partially recycle
waste heat from the exhausts of car engines, potentially leading
to significantly improved gas mileage. Thermoelectrics can also
be used for silent refrigerators that have no compressor or refigerant.
We recently predicted that the efficiency of thermoelectric energy conversion can approach the Carnot efficiency in materials with the following properties:
- Electron transport is limited to a narrow energy band that coincides with the energy where the Fermi function in the hot reservoir equals that of the cold reservoir.
- Weak electron-phonon coupling.
Under these conditions, electrons can be in "energy-specific equilibrium" in spite of the presence of a heat gradient, and heat can be used to create electric current almost reversibly (without "friction").
The above conditions can in principle be fulfilled at low temperatures (where electron-phonon coupling is suppressed) in one-dimensional semiconductor nanowires with a built-in energy filter, such as a double-barrier resonant tunneling structure.
Project goals:
- Proof-of-principle experiments demonstrating high thermoelectric efficiency in single nanowires at cryogenic temperatures.
- Exploration of the potential of this concept for applications around room temperature.
Dr. Ann Persson
Eric Hoffmann
Dr. Tammy Humphrey, Geneva
Lars Samuelson, Lund University , Sweden
Mark O'Dwyer, University of Wollongong , Australia
Linus Fröberg, Lund University , Sweden
H. Linke, T.E. Humphrey and M. O'Dwyer: Energy-specific
equilibrium in nanowires for efficient thermoelectric power generation.
Proceedings of Symposium F at the MRS Fall Meeting 2005
M. O'Dwyer, T. E. Humphrey and H. Linke: Concept study
for a high-efficiency nanowire-based thermoelectric.
Submitted to Nanotechnology. Preprint at
cond-mat/0601110
T. E. Humphrey and H. Linke: Reversible Thermoelectric
Nanomaterials. Phys. Rev. Lett. 94 096601
(2005)
T. E. Humphrey and H. Linke: Quantum, cyclic, and particle-exchange
heat engines. Physica E 29 (2005)
T.E. Humphrey and H. Linke: Reversible Quantum Brownian
Heat Engines for Electrons. Phys. Rev. Lett. 89, 116801
(2002)
News Coverage and Popular Science Reports
Putting brownian motion to work (Nature
Research Highlights, 30 August 2002)
A New Kind of Equilibrium (Phil Schewe and Ben
Stein in APS Physics News Update 727 #1, April 14, 2005)
Nanomaterials draw electricity from heat (Philipp
Ball for Nature Materials News, 24 March 2005)
Nanotechnology Now (April 5, 2005)
Recent Presentation
MRS Fall Meeting 2005 (Symposium F, invited) 
Office of Naval Research (ONR) and ONR Global
The Australian Research Council
Hi-Z Technology: Resource page for thermoelectrics R&D http://www.zts.com
Shakouri lab, UCSC http://quantum.soe.ucsc.edu/
Shi lab, University of Texas at Austin http://www.me.utexas.edu/~lishi/
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