On the physics and modeling of small semiconductor devices-III. Transient response in the finite collision-duration regime

D. K. Ferry; J. R. Barker

doi:10.1016/0038-1101(80)90035-0

On the physics and modeling of small semiconductor devices-III. Transient response in the finite collision-duration regime

D. K. Ferry, J. R. Barker

Arizona State University

Research output: Contribution to journal › Article › peer-review

35 Scopus citations

Abstract

The role of the finite, non-zero collision duration in high electric fields is examined for its effect on transient and over-shoot response of the carrier velocity and energy. The finite collision duration introduces a temporal retardation effect on the collisional relaxation mechanisms for energy and momentum. As a consequence, the effective temperature also undergoes an overshoot behavior, which leads to a general quickening of the total transient response. Calculations were performed for steady, homogeneous fields utilizing a displaced Maxwellian approach. These calculations were performed for GaAs and Si and have significance for sub-micron devices in these materials. The generally faster response leads to the prospect of improved high frequency properties over what is normally expected.

Original language	English (US)
Pages (from-to)	545-549
Number of pages	5
Journal	Solid State Electronics
Volume	23
Issue number	6
DOIs	https://doi.org/10.1016/0038-1101(80)90035-0
State	Published - Jun 1980

ASJC Scopus subject areas

Electronic, Optical and Magnetic Materials
Condensed Matter Physics
Electrical and Electronic Engineering
Materials Chemistry

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abstract = "The role of the finite, non-zero collision duration in high electric fields is examined for its effect on transient and over-shoot response of the carrier velocity and energy. The finite collision duration introduces a temporal retardation effect on the collisional relaxation mechanisms for energy and momentum. As a consequence, the effective temperature also undergoes an overshoot behavior, which leads to a general quickening of the total transient response. Calculations were performed for steady, homogeneous fields utilizing a displaced Maxwellian approach. These calculations were performed for GaAs and Si and have significance for sub-micron devices in these materials. The generally faster response leads to the prospect of improved high frequency properties over what is normally expected.",

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N2 - The role of the finite, non-zero collision duration in high electric fields is examined for its effect on transient and over-shoot response of the carrier velocity and energy. The finite collision duration introduces a temporal retardation effect on the collisional relaxation mechanisms for energy and momentum. As a consequence, the effective temperature also undergoes an overshoot behavior, which leads to a general quickening of the total transient response. Calculations were performed for steady, homogeneous fields utilizing a displaced Maxwellian approach. These calculations were performed for GaAs and Si and have significance for sub-micron devices in these materials. The generally faster response leads to the prospect of improved high frequency properties over what is normally expected.

AB - The role of the finite, non-zero collision duration in high electric fields is examined for its effect on transient and over-shoot response of the carrier velocity and energy. The finite collision duration introduces a temporal retardation effect on the collisional relaxation mechanisms for energy and momentum. As a consequence, the effective temperature also undergoes an overshoot behavior, which leads to a general quickening of the total transient response. Calculations were performed for steady, homogeneous fields utilizing a displaced Maxwellian approach. These calculations were performed for GaAs and Si and have significance for sub-micron devices in these materials. The generally faster response leads to the prospect of improved high frequency properties over what is normally expected.

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On the physics and modeling of small semiconductor devices-III. Transient response in the finite collision-duration regime

Abstract

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