Spectral force approach to solve the time-dependent Wigner-Liouville equation

2014 International Workshop on Computational Electronics (IWCE) Pub Date : 2014-06-03 DOI:10.1109/IWCE.2014.6865853
M. L. Van de Put, M. Thewissen, W. Magnus, B. Sorée, J. Sellier
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引用次数: 1

Abstract

The Wigner-Liouville (WL) equation is well suited to describe electronic transport in semiconductor devices. In the effective mass approximation the one dimensional WL equation reads ∂/∂t f(x, p, t) + p/m ∂/∂x f(x, p, t)-1/h2 ∫ dp' W(x, p-p')f(x, p', t) = 0; (1) with the Wigner kernel given by W(x, p) = -i/2π ∫ dx' exp (-i px'/h) [V (x + x'/2)-V (x-x'/2)].(2) The Wigner kernel introduces a non-local interaction with the potential V(x), in accordance with quantum theory. Unfortunately, even for this simple interaction the mathematical form includes a highly oscillatory component (exp [-i p·x/h]) which impedes stable numerical implementation based on finite differences or finite elements.
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求解时变Wigner-Liouville方程的谱力方法
Wigner-Liouville (WL)方程非常适合描述半导体器件中的电子输运。在有效质量近似中,一维WL方程为∂/∂t f(x, p, t) + p/m∂/∂x f(x, p, t)-1/h2∫dp' W(x, p', p)f(x, p', t) = 0;(1) W(x, p) = -i/2π∫dx' exp (-i px'/h) [V (x + x'/2)-V (x-x'/2)]给出的Wigner核。(2)根据量子理论,Wigner核引入了与势V(x)的非局域相互作用。不幸的是,即使对于这种简单的相互作用,数学形式也包括一个高度振荡的分量(exp [-i p·x/h]),这阻碍了基于有限差分或有限元素的稳定数值实现。
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2014 International Workshop on Computational Electronics (IWCE)
2014 International Workshop on Computational Electronics (IWCE)
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