Jens Uwe Nöckel

Welcome to the Micro-optics
and Quantum Chaos Group

Affiliations:

Department of Physics, University of Oregon
Oregon Center for Optics
Institute of Theoretical Science
Oregon Nanoscience and Microtechnologies Institute

Affiliates:

David Foster, former graduate student

Andrew Cook, graduate student

Computing: Some of my notes on computing related issues are available here.
Selected recent papers citing our work:: <a href= "recentcitations.html">Click here</a> to see a brief list.<br> If you had a more up-to-date browser, you would see a fancier display here.

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Where do you want to tunnel today ?

Briefly, my interests are in quantum chaos and semiclassical physics applied to microcavity optics, as well as the optical and transport properties of mesoscopic systems. The work is theoretical in nature, involving both analytical and numerical modelling of physics and engineering related problems.

This site introduces the work in my group, and provides numerous links to other places on the web that explain the context of what we do.

Umlaut alert:
J.U.Nöckel

The ö in my last name is pronounced like the vowel in "burn". If you can't find ö on your keyboard, just type Nockel. But when Germans don't have the umlaut on their keyboard, they replace ö by oe! Learn more from Mark Twain... (parody is the highest form of flattery), or perhaps from Monty Python. For the ultimate perspective on this subject, consult Jorge Luis Borges.

Think big - think Micro !

Microscience is the big brother of Nanoscience. I use this term because even the most "nano" structure won't do anything useful unless it is coupled to a much larger system (measurement apparatus, observer, universe ...). That's what I am interested in - essentially, it's what makes Nanoscience into Nanotechnology.

Examining the technological aspects of nano-and microscale systems seriously, one is invariably faced with a multiscale problem.

The twilight zone between micro and macro length scales is "mesoscopic physics". Historically, i.e. since the Eighties of the last century (the twentieth), mesoscopic physics had to deal with micro- and nanostructure experiments that were rather dirty, in the sense that disorder often dominated the behavior of small devices. Microstructures nowadays, on the other hand, profit from significant advances in fabrication technologies which lead to cleaner systems. Their properties are then dominated by boundary effects. Boundaries and interfaces between large and small systems are a central theme in microscience.

Although fabrication-technological advances were largely driven by the microelectronics industry, micro-optical devices have emerged as an important class of systems where fundamental problems of microscience have a direct impact upon applications. Micro-optics therefore has become the focus of my work since 1995, motivated by collaborations with experimental groups at Yale University, Lucent Technologies, France Telecom and Darmstadt University of Technology.

Details on these collaborations can be found in my bibliography; to see how these questions are connected with the theory of nonlinear dynamics and chaos, please take a look at the Hitchhiker's guide to dielectric cavities.

NNavigating (or IExploring) this site

A good way of getting an overview of this site is to browse the example systems by clicking on

For more programmatic information, you may want to start with

which describes my research interests and the context of my current work.

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