SiGe:C HBT transit time analysis based on hydrodynamic modeling using doping, composition and strained dependent SiGe:C carriers mobility and relaxation time

E. Ramirez-Garcia; M. Michaillat; F. Aniel; N. Zerounian; M. Enciso-Aguilar; D. Rideau

doi:10.1016/j.sse.2011.03.006

SiGe:C HBT transit time analysis based on hydrodynamic modeling using doping, composition and strained dependent SiGe:C carriers mobility and relaxation time

E. Ramirez-Garcia, M. Michaillat, F. Aniel, N. Zerounian, M. Enciso-Aguilar, D. Rideau

Escuela Superior de Ingeniería Mecánica y Eléctrica (ESIME), Unidad Zacatenco

Producción científica: Contribución a una revista › Artículo › revisión exhaustiva

6 Citas (Scopus)

Resumen

We present an original method for the detailed evaluation of different device region contributions to the whole SiGe:C heterojunction bipolar transistor transit time in the frame of modeling studies. This method is based on AC analysis with structures of several base widths. The two-dimensional hydrodynamic solver relies on analytical models of electron and hole mobilities, and of energy relaxation times, calculated from results of the Boltzmann Transport Equation in highly acceptor doped and strained SiGe:C, using a full band Monte Carlo solver. The simulation results are compared to DC and AC measurements and exhibit good agreement. The proposed transit time analysis scheme and the analytical model for mobilities and energy relaxation times may be used for device optimization, toward highest dynamic performances.

Idioma original	Inglés
Páginas (desde-hasta)	58-64
Número de páginas	7
Publicación	Solid-State Electronics
Volumen	61
N.º	1
DOI	https://doi.org/10.1016/j.sse.2011.03.006
Estado	Publicada - jul. 2011

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title = "SiGe:C HBT transit time analysis based on hydrodynamic modeling using doping, composition and strained dependent SiGe:C carriers mobility and relaxation time",

abstract = "We present an original method for the detailed evaluation of different device region contributions to the whole SiGe:C heterojunction bipolar transistor transit time in the frame of modeling studies. This method is based on AC analysis with structures of several base widths. The two-dimensional hydrodynamic solver relies on analytical models of electron and hole mobilities, and of energy relaxation times, calculated from results of the Boltzmann Transport Equation in highly acceptor doped and strained SiGe:C, using a full band Monte Carlo solver. The simulation results are compared to DC and AC measurements and exhibit good agreement. The proposed transit time analysis scheme and the analytical model for mobilities and energy relaxation times may be used for device optimization, toward highest dynamic performances.",

keywords = "Energy relaxation time, Hydrodynamic modeling, Minority electron mobility, Strained SiGe:C, Transit times",

author = "E. Ramirez-Garcia and M. Michaillat and F. Aniel and N. Zerounian and M. Enciso-Aguilar and D. Rideau",

year = "2011",

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T1 - SiGe:C HBT transit time analysis based on hydrodynamic modeling using doping, composition and strained dependent SiGe:C carriers mobility and relaxation time

AU - Ramirez-Garcia, E.

AU - Michaillat, M.

AU - Aniel, F.

AU - Zerounian, N.

AU - Enciso-Aguilar, M.

AU - Rideau, D.

PY - 2011/7

Y1 - 2011/7

N2 - We present an original method for the detailed evaluation of different device region contributions to the whole SiGe:C heterojunction bipolar transistor transit time in the frame of modeling studies. This method is based on AC analysis with structures of several base widths. The two-dimensional hydrodynamic solver relies on analytical models of electron and hole mobilities, and of energy relaxation times, calculated from results of the Boltzmann Transport Equation in highly acceptor doped and strained SiGe:C, using a full band Monte Carlo solver. The simulation results are compared to DC and AC measurements and exhibit good agreement. The proposed transit time analysis scheme and the analytical model for mobilities and energy relaxation times may be used for device optimization, toward highest dynamic performances.

AB - We present an original method for the detailed evaluation of different device region contributions to the whole SiGe:C heterojunction bipolar transistor transit time in the frame of modeling studies. This method is based on AC analysis with structures of several base widths. The two-dimensional hydrodynamic solver relies on analytical models of electron and hole mobilities, and of energy relaxation times, calculated from results of the Boltzmann Transport Equation in highly acceptor doped and strained SiGe:C, using a full band Monte Carlo solver. The simulation results are compared to DC and AC measurements and exhibit good agreement. The proposed transit time analysis scheme and the analytical model for mobilities and energy relaxation times may be used for device optimization, toward highest dynamic performances.

KW - Energy relaxation time

KW - Hydrodynamic modeling

KW - Minority electron mobility

KW - Strained SiGe:C

KW - Transit times

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U2 - 10.1016/j.sse.2011.03.006

DO - 10.1016/j.sse.2011.03.006

M3 - Artículo

SN - 0038-1101

VL - 61

SP - 58

EP - 64

JO - Solid-State Electronics

JF - Solid-State Electronics

IS - 1

ER -

SiGe:C HBT transit time analysis based on hydrodynamic modeling using doping, composition and strained dependent SiGe:C carriers mobility and relaxation time

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