Numerical Simulation of Thermal Runaway Phenomena in Silicon Semiconductor Devices

A mathematical model for heat production due to thermal excitation of conductive electrons and positive holes in semiconductor pn junction is derived and discussed. The model is applied to simulate the thermal runaway phenomena in power electronics semiconductor devices. Our discussion focuses espec...

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Veröffentlicht in:	Nihon Kikai Gakkai rombunshuu. B hen 1998/11/25, Vol.64(627), pp.3814-3822
Hauptverfasser:	SHIODA, Kazunori, OOBU, Toshiharu, KIJIMA, Kenji
Format:	Artikel
Sprache:	eng ; jpn
Schlagworte:	Electronic Equipment Electronics
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container_title	Nihon Kikai Gakkai rombunshuu. B hen
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creator	SHIODA, Kazunori OOBU, Toshiharu KIJIMA, Kenji
description	A mathematical model for heat production due to thermal excitation of conductive electrons and positive holes in semiconductor pn junction is derived and discussed. The model is applied to simulate the thermal runaway phenomena in power electronics semiconductor devices. Our discussion focuses especially on the modeling of unexpected huge current due to excessive temperature rise. Calculated dynamics of temperature distributions of silicon wafer while cooling performance decreases proved it possible that silicon wafer might be heated over its melting point in a few miliseconds. Our results indicate that if local hot spot arises in wafer, thermal excitation of intrinsic carries increases diffusion current of minor carriers and recombination current in depletion layer of pn junction. And it appears to be important that cooling performance should be uniform on the wafer to avoid the growth of hot spots and thermal runaway itself.
doi_str_mv	10.1299/kikaib.64.3814
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issn	0387-5016 1884-8346
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source	J-STAGE Free; Elektronische Zeitschriftenbibliothek - Frei zugängliche E-Journals
subjects	Electronic Equipment Electronics
title	Numerical Simulation of Thermal Runaway Phenomena in Silicon Semiconductor Devices
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