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==Click on the links below to access the descriptions==
 
==Click on the links below to access the descriptions==
 
* [https://iis-people.ee.ethz.ch/~kgf/pics/2015-11-zurich/D71_2443_lrg.jpg Cryogenic measurements and modeling of electrical devices]
 
 
* [[Media:Something_really_interesting.pdf|Cryogenic measurements and modeling of electrical devices]]
 
* [[Media:Something_really_interesting.pdf|Cryogenic measurements and modeling of electrical devices]]
  

Revision as of 11:56, 29 November 2018

Click on the links below to access the descriptions


Nano-Device Physics (Prof. A. Schenk)

Research in the Nano-Device Physics Group is concerned with nanoelectronic devices and technologies, first-principle modeling of carrier transport, the advancement of transport solvers both for quantum structures and scattering-dominated devices, and the development of new numerical techniques. For technical and economical reasons modeling and optimization by numerical simulations based on semiconductor physics (Technology Computer Aided Design - TCAD) complete or replace experimental development techniques. The TCAD concept is a scientific challenge as well as a technical methodology, therefore it requires research collaborations between academia and industry. Our TCAD activities comprise the study and modeling of physical phenomena in current and future CMOS technologies as well as in post-CMOS and emerging research devices.

Computational Nanoelectronics (Prof. M. Luisier)

The Computational Nanoelectronics group was established in 2011. It develops and applies numerical algorithms to investigate nanodevices ranging from next generation transistors to thermoelectric generators and optoelectronic devices. While theories based on classical physics have been very successful in helping experimentalists design microelectronic devices, new approaches based on quantum mechanics are required to accurately model today nanoscale transistors and solar cells and to predict their characteristics even before they are fabricated. As simulation tool, we use OMEN, a state-of-the-art, massively parallel, quantum transport solver. OMEN was the first full-band, atomistic, and multi-dimensional device simulator capable of treating realistically extended nanostructures. It has been tested up to 220'000 cores on some of the largest available supercomputers, reaching a sustained performance of more than 1 Petaflop/s, while investigating nanowire, ultra-thin-body, graphene nanoribbon, carbon nanotube field-effect and band-to-band tunneling transistors. By further extending the physical models of OMEN and by applying them to novel structures, we expect to discover new phenomena governing the behavior of nanoelectronic devices and bring new insight into their physics.

Available Projects

We are still looking for students/partners to work on the following projects


Links