Wigner Monte Carlo approach to quantum transport in nanodevices

The Wigner Monte Carlo approach is shown to provide an efficient way to study quantum transport in the presence of scattering and to connect semi-classical to quantum transport. The study of resonant tunneling diodes highlights the physics of the impact of scattering on resonant tunneling, and on el...

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Hauptverfasser:	Dollfus, P., Querlioz, D., Saint-Martin, J., Do, V.-N., Bournel, A.
Format:	Tagungsbericht
Sprache:	eng
Schlagworte:	Equations Green function Logic gates Mathematical model Monte Carlo methods MOSFETs Phonons Quantum theory Resonant tunneling devices Resonant Tunneling Diodes Scattering Tunneling Wigner distributions
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creator	Dollfus, P. Querlioz, D. Saint-Martin, J. Do, V.-N. Bournel, A.
description	The Wigner Monte Carlo approach is shown to provide an efficient way to study quantum transport in the presence of scattering and to connect semi-classical to quantum transport. The study of resonant tunneling diodes highlights the physics of the impact of scattering on resonant tunneling, and on electron decoherence and localization. The simulation of nano-MOSFET evidences a mixed regime, where both quantum transport and scattering play a significant role.
doi_str_mv	10.1109/SISPAD.2008.4648291
format	Conference Proceeding
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source	IEEE Electronic Library (IEL) Conference Proceedings
subjects	Equations Green function Logic gates Mathematical model Monte Carlo methods MOSFETs Phonons Quantum theory Resonant tunneling devices Resonant Tunneling Diodes Scattering Tunneling Wigner distributions
title	Wigner Monte Carlo approach to quantum transport in nanodevices
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