2009
DOI: 10.1007/s10825-009-0281-3
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Wigner-Boltzmann Monte Carlo approach to nanodevice simulation: from quantum to semiclassical transport

Abstract: In this paper, we review and extend our recent works based on the Monte Carlo method to solve the Wigner-Boltzmann transport equation and model semiconductor nanodevices. After presenting the different possible approaches to quantum mechanical modelling, the formalism and the theoretical framework are described together with the particle Monte Carlo implementation using a technique fully compatible with semiclassical simulation. Examples are given to highlight the importance of considering both quantum and sca… Show more

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Cited by 37 publications
(27 citation statements)
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“…In this work, we consider a GaAs-based device, so the relevant scattering mechanisms are with polar optical phonons and ionized donors 28 . Well-established methods of solving the openboundary WBTE include the finite-difference approaches 13,14,29 and Monte Carlo methods 20,[30][31][32][33] . We solve Eq.…”
Section: System and Model Descriptionmentioning
confidence: 99%
“…In this work, we consider a GaAs-based device, so the relevant scattering mechanisms are with polar optical phonons and ionized donors 28 . Well-established methods of solving the openboundary WBTE include the finite-difference approaches 13,14,29 and Monte Carlo methods 20,[30][31][32][33] . We solve Eq.…”
Section: System and Model Descriptionmentioning
confidence: 99%
“…We note that even a onedimensional problem involves the complete 3D wave vector space. The equation has been derived from first principles only recently for interactions with ionized impurities [15] and with phonons [16]. The two approaches are very different and involve a set of assumptions and approximations: a large number of dopant atoms, a fast collision approximation, a weak scattering limit and an equilibrium phonon system.…”
Section: Wigner-boltzmann Equationmentioning
confidence: 99%
“…Additionally, in such device scattering has been shown to cause the emergence of semi-classical transport, i.e. of the localization of electrons [36].…”
Section: Transition Between Quantum and Semi-classical Transportmentioning
confidence: 99%