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Autori principali: Huang, Zifeng, Liang, Jianbo, Wang, Yuxiang, Sun, Zixuan, Shigekawa, Naoteru, Li, Ming, Wang, Runsheng, Cheng, Zhe
Natura: Preprint
Pubblicazione: 2025
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Accesso online:https://arxiv.org/abs/2504.20820
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author Huang, Zifeng
Liang, Jianbo
Wang, Yuxiang
Sun, Zixuan
Shigekawa, Naoteru
Li, Ming
Wang, Runsheng
Cheng, Zhe
author_facet Huang, Zifeng
Liang, Jianbo
Wang, Yuxiang
Sun, Zixuan
Shigekawa, Naoteru
Li, Ming
Wang, Runsheng
Cheng, Zhe
contents The role of doping in tailoring thermal transport in semiconductors is critical for efficient thermal management in electronic devices. While the effects of doping have been extensively studied to tune electrical properties, its impact on thermal transport has not yet been thoroughly explored, particularly with respect to experimental investigations into exceptionally strong non-Rayleigh defect-phonon scattering phenomena. Herein, by combining the high-quality growth and advanced characterizations of cubic silicon carbide single crystals with well controlled boron doping, we experimentally observe anomalous strong defect-phonon scatterings, among the strongest reported in common semiconductors, that exceeds the predictions of the classic mass difference model by tens of times in magnitude. The measured thermal conductivity of doped 3C SiC match excellently with those predicted by first principle calculations in which resonant scattering of low frequency phonon is considered. Our findings not only shed light on the fundamental understanding of defect-phonon interactions and will also impact applications such as thermal management of electronics.
format Preprint
id arxiv_https___arxiv_org_abs_2504_20820
institution arXiv
publishDate 2025
record_format arxiv
spellingShingle Experimental Observation of Extremely Strong Defect-Phonon Scatterings in Semiconductor Single Crystals
Huang, Zifeng
Liang, Jianbo
Wang, Yuxiang
Sun, Zixuan
Shigekawa, Naoteru
Li, Ming
Wang, Runsheng
Cheng, Zhe
Materials Science
Applied Physics
The role of doping in tailoring thermal transport in semiconductors is critical for efficient thermal management in electronic devices. While the effects of doping have been extensively studied to tune electrical properties, its impact on thermal transport has not yet been thoroughly explored, particularly with respect to experimental investigations into exceptionally strong non-Rayleigh defect-phonon scattering phenomena. Herein, by combining the high-quality growth and advanced characterizations of cubic silicon carbide single crystals with well controlled boron doping, we experimentally observe anomalous strong defect-phonon scatterings, among the strongest reported in common semiconductors, that exceeds the predictions of the classic mass difference model by tens of times in magnitude. The measured thermal conductivity of doped 3C SiC match excellently with those predicted by first principle calculations in which resonant scattering of low frequency phonon is considered. Our findings not only shed light on the fundamental understanding of defect-phonon interactions and will also impact applications such as thermal management of electronics.
title Experimental Observation of Extremely Strong Defect-Phonon Scatterings in Semiconductor Single Crystals
topic Materials Science
Applied Physics
url https://arxiv.org/abs/2504.20820