Electronic scattering leads to anomalous thermal conductivity of n-type cubic silicon carbide in the high-temperature region

Xiao Yong Fang; Kun Wang; Zhi Ling Hou; Hai Bo Jin; Ya Qin Li; Mao Sheng Cao

doi:10.1088/0953-8984/24/44/445802

Electronic scattering leads to anomalous thermal conductivity of n-type cubic silicon carbide in the high-temperature region

Xiao Yong Fang^*, Kun Wang, Zhi Ling Hou, Hai Bo Jin, Ya Qin Li, Mao Sheng Cao

^*此作品的通讯作者

材料学院

科研成果: 期刊稿件 › 文章 › 同行评审

14 引用（Scopus）

摘要

This study simulates thermal conductivity via a carrier scattering mechanism and the related parameters are obtained based on first principles for intrinsic and doped silicon carbide (SiC) over a temperature range of 300-1450K. The theoretical analysis results show that the thermal conductivity decreases with increasing temperature along each orientation for both cubic SiC (3C-SiC) and doped SiC. Compared with traditional calculations, the thermal conductivity of doped SiC is larger than that of intrinsic SiC in the high-temperature region. In particular, the n-type thermal conductivity is higher than the p-type thermal conductivity because of the scattering probability between electrons and the ionization impurity increasing with the temperature. Our studies are important to a further understanding of thermal transportation.

源语言	英语
文章编号	445802
期刊	Journal of Physics Condensed Matter
卷	24
期	44
DOI	https://doi.org/10.1088/0953-8984/24/44/445802
出版状态	已出版 - 7 11月 2012

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Fang, X. Y., Wang, K., Hou, Z. L., Jin, H. B., Li, Y. Q., & Cao, M. S. (2012). Electronic scattering leads to anomalous thermal conductivity of n-type cubic silicon carbide in the high-temperature region. Journal of Physics Condensed Matter, 24(44), 文章 445802. https://doi.org/10.1088/0953-8984/24/44/445802

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title = "Electronic scattering leads to anomalous thermal conductivity of n-type cubic silicon carbide in the high-temperature region",

abstract = "This study simulates thermal conductivity via a carrier scattering mechanism and the related parameters are obtained based on first principles for intrinsic and doped silicon carbide (SiC) over a temperature range of 300-1450K. The theoretical analysis results show that the thermal conductivity decreases with increasing temperature along each orientation for both cubic SiC (3C-SiC) and doped SiC. Compared with traditional calculations, the thermal conductivity of doped SiC is larger than that of intrinsic SiC in the high-temperature region. In particular, the n-type thermal conductivity is higher than the p-type thermal conductivity because of the scattering probability between electrons and the ionization impurity increasing with the temperature. Our studies are important to a further understanding of thermal transportation.",

author = "Fang, {Xiao Yong} and Kun Wang and Hou, {Zhi Ling} and Jin, {Hai Bo} and Li, {Ya Qin} and Cao, {Mao Sheng}",

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AU - Fang, Xiao Yong

AU - Wang, Kun

AU - Hou, Zhi Ling

AU - Jin, Hai Bo

AU - Li, Ya Qin

AU - Cao, Mao Sheng

PY - 2012/11/7

Y1 - 2012/11/7

N2 - This study simulates thermal conductivity via a carrier scattering mechanism and the related parameters are obtained based on first principles for intrinsic and doped silicon carbide (SiC) over a temperature range of 300-1450K. The theoretical analysis results show that the thermal conductivity decreases with increasing temperature along each orientation for both cubic SiC (3C-SiC) and doped SiC. Compared with traditional calculations, the thermal conductivity of doped SiC is larger than that of intrinsic SiC in the high-temperature region. In particular, the n-type thermal conductivity is higher than the p-type thermal conductivity because of the scattering probability between electrons and the ionization impurity increasing with the temperature. Our studies are important to a further understanding of thermal transportation.

AB - This study simulates thermal conductivity via a carrier scattering mechanism and the related parameters are obtained based on first principles for intrinsic and doped silicon carbide (SiC) over a temperature range of 300-1450K. The theoretical analysis results show that the thermal conductivity decreases with increasing temperature along each orientation for both cubic SiC (3C-SiC) and doped SiC. Compared with traditional calculations, the thermal conductivity of doped SiC is larger than that of intrinsic SiC in the high-temperature region. In particular, the n-type thermal conductivity is higher than the p-type thermal conductivity because of the scattering probability between electrons and the ionization impurity increasing with the temperature. Our studies are important to a further understanding of thermal transportation.

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Electronic scattering leads to anomalous thermal conductivity of n-type cubic silicon carbide in the high-temperature region

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