A new insight on the thermal resistance source of diamond -SiC interface: Based on non-equilibrium molecular dynamics

A new insight on the thermal resistance source of diamond -SiC interface: Based on non-equilibrium molecular dynamics

Diamond/silicon carbide (diamond/SiC) is the future development of thermal management materials for it's high thermal conductivity, and interface research is the key to improve the performance of diamond/SiC. In this paper, we focus on the transition layer SixC(1-x) between diamond and SiC for...

Full description

Saved in:
Bibliographic Details
Main Authors: Kunlong Zhao, Huagang Lyu, Biao Wang, Zhijie Ye, Wenxin Cao, Dongmeng Shi, Xiaobin Hao, Sen Zhang, Zhuochao Wang, Xiaolei Wang, Xingchun Xu, Jiaqi Zhu
Format: Article
Language:English
Published: Elsevier 2025-07-01
Series:Journal of Materials Research and Technology
Subjects:
Silicon carbide
Diamond
Interfacial thermal resistance
Non-equilibrium molecular dynamics
Phonon density of states
Phonon group velocity
Online Access:http://www.sciencedirect.com/science/article/pii/S2238785425014498
Tags: Add Tag
No Tags, Be the first to tag this record!
Description
Summary:Diamond/silicon carbide (diamond/SiC) is the future development of thermal management materials for it's high thermal conductivity, and interface research is the key to improve the performance of diamond/SiC. In this paper, we focus on the transition layer SixC(1-x) between diamond and SiC for the first time, and investigate its influence on heat transfer properties by using non-equilibrium molecular dynamics simulations. The source of interfacial thermal resistance (ITR) of the transition layer is analyzed through phonon density of states and phonon group velocity. The results show that the presence of 5 nm SixC(1-x) transition layer leads to the ITR of 2.96 × 10−9 m2K/W between diamond and SiC, and with the increase of transition layer thickness, the ITR can reach up to 4.29 × 10−9 m2K/W. The range of ITR is significantly higher than the traditionally accepted value of 6 × 10−10 m2K/W. The influence of atom doping mode and lattice constant on the ITR range is relatively limited, whereas the impact of atom distribution mode more significant. Based on the phonon group velocity analysis, it is evident that the disordered distribution of silicon atoms in Si0.2C0.8 significantly reduces the thermal conductivity of the transition layer. This disordered distribution is also the main source of ITR. This study provides a new insight into the origin of ITR between diamond and SiC, offering a reference for the interfacial engineering design of high-thermal conductivity diamond/SiC composites.
ISSN:2238-7854

Similar Items