A Direct Solver for 2D Non-Stationary Boltzmann-Poisson Systems for Semiconductor Devices: A MESFET Simulation by WENO-Boltzmann Schemes

José A. Carrillo; Irene M. Gamba; Armando Majorana; Chi Wang Shu

doi:10.1023/B:JCEL.0000011455.74817.35

A Direct Solver for 2D Non-Stationary Boltzmann-Poisson Systems for Semiconductor Devices: A MESFET Simulation by WENO-Boltzmann Schemes

José A. Carrillo, Irene M. Gamba, Armando Majorana, Chi Wang Shu

Departament de Matemàtiques

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© 2003, Kluwer Academic Publishers. We present preliminary results of a high order WENO scheme applied to deterministic computations for two dimensional formulation of the transients for the Boltzmann-Poisson system describing electron transport in semiconductor devices. The collisional term models optical-phonon interactions which become dominant under strong energetic conditions corresponding to nanoscale active regions under applied bias. We treat the Boltzmann Transport equation in a spherical coordinate system for the wave-vector space. The problem is three dimensional in the wave-vector space and two dimensional in the physical space, plus the time variable driving to steady states. The new formulation avoids the singularity due to the spherical coordinate system.

Idioma original	Anglès
Pàgines (de-a)	375-380
Revista	Journal of Computational Electronics
Volum	2
Número	2-4
DOIs	https://doi.org/10.1023/B:JCEL.0000011455.74817.35
Estat de la publicació	Publicada - 1 de des. 2003

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10.1023/B:JCEL.0000011455.74817.35

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title = "A Direct Solver for 2D Non-Stationary Boltzmann-Poisson Systems for Semiconductor Devices: A MESFET Simulation by WENO-Boltzmann Schemes",

abstract = "{\textcopyright} 2003, Kluwer Academic Publishers. We present preliminary results of a high order WENO scheme applied to deterministic computations for two dimensional formulation of the transients for the Boltzmann-Poisson system describing electron transport in semiconductor devices. The collisional term models optical-phonon interactions which become dominant under strong energetic conditions corresponding to nanoscale active regions under applied bias. We treat the Boltzmann Transport equation in a spherical coordinate system for the wave-vector space. The problem is three dimensional in the wave-vector space and two dimensional in the physical space, plus the time variable driving to steady states. The new formulation avoids the singularity due to the spherical coordinate system.",

keywords = "Boltzmann-Poisson system for semiconductors, spherical coordinate system, WENO scheme",

author = "Carrillo, \{Jos{\'e} A.\} and Gamba, \{Irene M.\} and Armando Majorana and Shu, \{Chi Wang\}",

year = "2003",

month = dec,

day = "1",

doi = "10.1023/B:JCEL.0000011455.74817.35",

language = "English",

volume = "2",

pages = "375--380",

journal = "Journal of Computational Electronics",

issn = "1569-8025",

publisher = "Springer",

number = "2-4",

}

A Direct Solver for 2D Non-Stationary Boltzmann-Poisson Systems for Semiconductor Devices: A MESFET Simulation by WENO-Boltzmann Schemes. / Carrillo, José A.; Gamba, Irene M.; Majorana, Armando et al.
In: Journal of Computational Electronics, Vol. 2, Núm. 2-4, 01.12.2003, pàg. 375-380.

Producció científica: Contribució a revista › Article › Recerca › Avaluat per experts

TY - JOUR

T1 - A Direct Solver for 2D Non-Stationary Boltzmann-Poisson Systems for Semiconductor Devices: A MESFET Simulation by WENO-Boltzmann Schemes

AU - Carrillo, José A.

AU - Gamba, Irene M.

AU - Majorana, Armando

AU - Shu, Chi Wang

PY - 2003/12/1

Y1 - 2003/12/1

N2 - © 2003, Kluwer Academic Publishers. We present preliminary results of a high order WENO scheme applied to deterministic computations for two dimensional formulation of the transients for the Boltzmann-Poisson system describing electron transport in semiconductor devices. The collisional term models optical-phonon interactions which become dominant under strong energetic conditions corresponding to nanoscale active regions under applied bias. We treat the Boltzmann Transport equation in a spherical coordinate system for the wave-vector space. The problem is three dimensional in the wave-vector space and two dimensional in the physical space, plus the time variable driving to steady states. The new formulation avoids the singularity due to the spherical coordinate system.

AB - © 2003, Kluwer Academic Publishers. We present preliminary results of a high order WENO scheme applied to deterministic computations for two dimensional formulation of the transients for the Boltzmann-Poisson system describing electron transport in semiconductor devices. The collisional term models optical-phonon interactions which become dominant under strong energetic conditions corresponding to nanoscale active regions under applied bias. We treat the Boltzmann Transport equation in a spherical coordinate system for the wave-vector space. The problem is three dimensional in the wave-vector space and two dimensional in the physical space, plus the time variable driving to steady states. The new formulation avoids the singularity due to the spherical coordinate system.

KW - Boltzmann-Poisson system for semiconductors

KW - spherical coordinate system

KW - WENO scheme

UR - https://www.scopus.com/pages/publications/29144517213

U2 - 10.1023/B:JCEL.0000011455.74817.35

DO - 10.1023/B:JCEL.0000011455.74817.35

M3 - Article

SN - 1569-8025

VL - 2

SP - 375

EP - 380

JO - Journal of Computational Electronics

JF - Journal of Computational Electronics

IS - 2-4

ER -

A Direct Solver for 2D Non-Stationary Boltzmann-Poisson Systems for Semiconductor Devices: A MESFET Simulation by WENO-Boltzmann Schemes

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