Particle-grid techniques for semiclassical and quantum transport simulations

Author

Schwaha, P. ; Nedjalkov, M. ; Selberherr, S. ; Dimov, I.

Author_Institution

Shenteq s.r.o., Bratisalva, Slovakia

fYear

2012

fDate

22-25 May 2012

Firstpage

1

Lastpage

3

Abstract

Particle simulation techniques utilizing classical or quantum weights commonly involve a phase space grid for the calculation of averages. Properties of alternative particle-grid simulation strategies are investigated by using an experiment highly sensitive to variance. It is provided by the fine structure of entangled electron states subject to scattering with phonons. As the process of evolution describes decoherence and transition from quantum to classical our analysis concerns both transport regimes. An algorithm based on randomization-annihilation of particles shows better performance than an Ensemble Monte Carlo method.

Keywords

fine structure; phase space methods; phonons; quantum entanglement; decoherence; entangled electron states; fine structure; particle simulation technique; particle-grid techniques; phase space grid; phonons; quantum transport simulation; randomization annihilation; semiclassical simulation; Electromagnetic compatibility; Microelectronics; Monte Carlo methods; Numerical models; Random access memory; Scattering; Trajectory;

fLanguage

English

Publisher

ieee

Conference_Titel

Computational Electronics (IWCE), 2012 15th International Workshop on

Conference_Location

Madison, WI

Print_ISBN

978-1-4673-0705-5

Type

conf

DOI

10.1109/IWCE.2012.6242860

Filename

6242860