Theory of High Field Transport in β-Ga2O3

Krishnendu Ghosh; Uttam Singisetti

doi:10.1142/9789811216480_0008

Theory of High Field Transport in β-Ga₂O₃

Krishnendu Ghosh
, Uttam Singisetti

Department of Electrical Engineering

Intel
SUNY Buffalo

Research output: Chapter in Book/Report/Conference proceeding › Chapter › peer-review

Abstract

We present a comprehensive review of high-field transport properties in an emerging and trending ultra-widebandgap semiconductor β-Ga₂O₃. The focus is on the theoretical understanding of the microscopic mechanisms that control the dynamics of farfrom- equilibrium electrons. A manifold of density functional calculations and Boltzmann theory based transport formalism unravels the behavior of the electron distribution under a varied range of external electric fields. The key high field transport properties that govern electronic device performance, like velocity and ionization co-effcients, are enlightened in detail with physical insights. Anisotropies in the above transport co-effcients are probed from the microscopic investigation of bandstructure, electron-phonon interactions, and electron-electron interactions.

Original language	English
Title of host publication	Wide Bandgap Semiconductor Electronics and Devices
Publisher	World Scientific Publishing Co.
Pages	145-161
Number of pages	17
ISBN (Electronic)	9789811216480
DOIs	https://doi.org/10.1142/9789811216480_0008
State	Published - Jan 1 2019

Keywords

GaO
High field transport
Impact ionization
Velocity

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10.1142/9789811216480_0008

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title = "Theory of High Field Transport in β-Ga2O3",

abstract = "We present a comprehensive review of high-field transport properties in an emerging and trending ultra-widebandgap semiconductor β-Ga2O3. The focus is on the theoretical understanding of the microscopic mechanisms that control the dynamics of farfrom- equilibrium electrons. A manifold of density functional calculations and Boltzmann theory based transport formalism unravels the behavior of the electron distribution under a varied range of external electric fields. The key high field transport properties that govern electronic device performance, like velocity and ionization co-effcients, are enlightened in detail with physical insights. Anisotropies in the above transport co-effcients are probed from the microscopic investigation of bandstructure, electron-phonon interactions, and electron-electron interactions.",

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AU - Singisetti, Uttam

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N2 - We present a comprehensive review of high-field transport properties in an emerging and trending ultra-widebandgap semiconductor β-Ga2O3. The focus is on the theoretical understanding of the microscopic mechanisms that control the dynamics of farfrom- equilibrium electrons. A manifold of density functional calculations and Boltzmann theory based transport formalism unravels the behavior of the electron distribution under a varied range of external electric fields. The key high field transport properties that govern electronic device performance, like velocity and ionization co-effcients, are enlightened in detail with physical insights. Anisotropies in the above transport co-effcients are probed from the microscopic investigation of bandstructure, electron-phonon interactions, and electron-electron interactions.

AB - We present a comprehensive review of high-field transport properties in an emerging and trending ultra-widebandgap semiconductor β-Ga2O3. The focus is on the theoretical understanding of the microscopic mechanisms that control the dynamics of farfrom- equilibrium electrons. A manifold of density functional calculations and Boltzmann theory based transport formalism unravels the behavior of the electron distribution under a varied range of external electric fields. The key high field transport properties that govern electronic device performance, like velocity and ionization co-effcients, are enlightened in detail with physical insights. Anisotropies in the above transport co-effcients are probed from the microscopic investigation of bandstructure, electron-phonon interactions, and electron-electron interactions.

KW - GaO

KW - High field transport

KW - Impact ionization

KW - Velocity

UR - https://www.scopus.com/pages/publications/85126402993

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DO - 10.1142/9789811216480_0008

M3 - Chapter

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SP - 145

EP - 161

BT - Wide Bandgap Semiconductor Electronics and Devices

PB - World Scientific Publishing Co.

ER -

Theory of High Field Transport in β-Ga₂O₃

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Keywords

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