A perspective on mechanism of heat transfer and performance optimization in advanced thermal interface materials

Chen Liang; Jingtao Hong; Cheng Wan; Xinkai Ma; Zhiteng Wang; Xiuchen Zhao; Aijun Hou; Denis Nika; Yongjun Huo; Gang Zhang

doi:10.1063/5.0250727

A perspective on mechanism of heat transfer and performance optimization in advanced thermal interface materials

Chen Liang, Jingtao Hong, Cheng Wan, Xinkai Ma, Zhiteng Wang, Xiuchen Zhao, Aijun Hou, Denis Nika^*, Yongjun Huo^*, Gang Zhang^*

^*Corresponding author for this work

School of Material Science and Engineering

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

Abstract

In recent years, thermal interface materials (TIMs) have garnered increasing attention in the field of thermal management for electronic devices. By effectively bridging the gap between electronic components and heat sinks, these materials significantly enhance heat transfer efficiency. This paper systematically reviews and analyzes the mechanisms, and the influencing factors associated with TIMs composed of graphene, carbon nanotubes, MXene, boron nitride compounds, and metal nanowires over recent years. Additionally, it delves into the challenges faced by these materials and explores its future research directions in thermal management. Future research endeavors are anticipated to focus on innovative designs for thermal conductivity networks in order to achieve further enhancements in the TIMs performance, ultimately paving the way for their practical application and commercialization.

Original language	English
Article number	070501
Journal	Applied Physics Letters
Volume	126
Issue number	7
DOIs	http://doi.org/10.1063/5.0250727
Publication status	Published - 17 Feb 2025

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abstract = "In recent years, thermal interface materials (TIMs) have garnered increasing attention in the field of thermal management for electronic devices. By effectively bridging the gap between electronic components and heat sinks, these materials significantly enhance heat transfer efficiency. This paper systematically reviews and analyzes the mechanisms, and the influencing factors associated with TIMs composed of graphene, carbon nanotubes, MXene, boron nitride compounds, and metal nanowires over recent years. Additionally, it delves into the challenges faced by these materials and explores its future research directions in thermal management. Future research endeavors are anticipated to focus on innovative designs for thermal conductivity networks in order to achieve further enhancements in the TIMs performance, ultimately paving the way for their practical application and commercialization.",

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AU - Liang, Chen

AU - Hong, Jingtao

AU - Wan, Cheng

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AU - Wang, Zhiteng

AU - Zhao, Xiuchen

AU - Hou, Aijun

AU - Nika, Denis

AU - Huo, Yongjun

AU - Zhang, Gang

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AB - In recent years, thermal interface materials (TIMs) have garnered increasing attention in the field of thermal management for electronic devices. By effectively bridging the gap between electronic components and heat sinks, these materials significantly enhance heat transfer efficiency. This paper systematically reviews and analyzes the mechanisms, and the influencing factors associated with TIMs composed of graphene, carbon nanotubes, MXene, boron nitride compounds, and metal nanowires over recent years. Additionally, it delves into the challenges faced by these materials and explores its future research directions in thermal management. Future research endeavors are anticipated to focus on innovative designs for thermal conductivity networks in order to achieve further enhancements in the TIMs performance, ultimately paving the way for their practical application and commercialization.

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A perspective on mechanism of heat transfer and performance optimization in advanced thermal interface materials

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