Special Important Aspects of the Thomson Effect

Igor Lashkevych; J. E. Velázquez; Oleg Yu Titov; Yuri G. Gurevich

doi:10.1007/s11664-018-6205-x

Special Important Aspects of the Thomson Effect

Igor Lashkevych, J. E. Velázquez, Oleg Yu Titov, Yuri G. Gurevich

Unidad Profesional Interdisciplinaria de Ingeniería y Tecnologías Avanzadas (UPIITA)

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

6 Scopus citations

Abstract

A comprehensive study of the mechanisms of heating and cooling originating from an electrical current in semiconductor devices is reported. The variation in temperature associated with the Peltier effect is not related to the presence of heat sources and sinks if the heat flux is correctly determined. The Thomson effect is commonly regarded as a heat source/sink proportional to the Thomson coefficient, which is added to the Joule heating. In the present work, we will show that this formulation of the Thomson effect is not sufficiently clear. When the heat flux is correctly defined, the Thomson heat source/sink is proportional to the Seebeck coefficient. In the conditions in which the Peltier effect takes place, the temperature gradient is created, and, consequently, the Thomson effect will occur naturally.

Original language	English
Pages (from-to)	3189-3192
Number of pages	4
Journal	Journal of Electronic Materials
Volume	47
Issue number	6
DOIs	https://doi.org/10.1007/s11664-018-6205-x
State	Published - 1 Jun 2018

Keywords

Joule effect
Peltier effect
Thomson effect

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10.1007/s11664-018-6205-x

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title = "Special Important Aspects of the Thomson Effect",

abstract = "A comprehensive study of the mechanisms of heating and cooling originating from an electrical current in semiconductor devices is reported. The variation in temperature associated with the Peltier effect is not related to the presence of heat sources and sinks if the heat flux is correctly determined. The Thomson effect is commonly regarded as a heat source/sink proportional to the Thomson coefficient, which is added to the Joule heating. In the present work, we will show that this formulation of the Thomson effect is not sufficiently clear. When the heat flux is correctly defined, the Thomson heat source/sink is proportional to the Seebeck coefficient. In the conditions in which the Peltier effect takes place, the temperature gradient is created, and, consequently, the Thomson effect will occur naturally.",

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AU - Lashkevych, Igor

AU - Velázquez, J. E.

AU - Titov, Oleg Yu

AU - Gurevich, Yuri G.

PY - 2018/6/1

Y1 - 2018/6/1

N2 - A comprehensive study of the mechanisms of heating and cooling originating from an electrical current in semiconductor devices is reported. The variation in temperature associated with the Peltier effect is not related to the presence of heat sources and sinks if the heat flux is correctly determined. The Thomson effect is commonly regarded as a heat source/sink proportional to the Thomson coefficient, which is added to the Joule heating. In the present work, we will show that this formulation of the Thomson effect is not sufficiently clear. When the heat flux is correctly defined, the Thomson heat source/sink is proportional to the Seebeck coefficient. In the conditions in which the Peltier effect takes place, the temperature gradient is created, and, consequently, the Thomson effect will occur naturally.

AB - A comprehensive study of the mechanisms of heating and cooling originating from an electrical current in semiconductor devices is reported. The variation in temperature associated with the Peltier effect is not related to the presence of heat sources and sinks if the heat flux is correctly determined. The Thomson effect is commonly regarded as a heat source/sink proportional to the Thomson coefficient, which is added to the Joule heating. In the present work, we will show that this formulation of the Thomson effect is not sufficiently clear. When the heat flux is correctly defined, the Thomson heat source/sink is proportional to the Seebeck coefficient. In the conditions in which the Peltier effect takes place, the temperature gradient is created, and, consequently, the Thomson effect will occur naturally.

KW - Joule effect

KW - Peltier effect

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JO - Journal of Electronic Materials

JF - Journal of Electronic Materials

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ER -

Special Important Aspects of the Thomson Effect

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