声子
凝聚态物理
超晶格
热导率
玻尔兹曼方程
材料科学
散射
声子散射
平均自由程
工作(物理)
热的
格子(音乐)
热传导
垂直的
热电材料
拉曼散射
密度泛函理论
电导率
散射率
作者
Y LI,Pan Zhang,S Chen,Yong Liu,Zhihong Lu,王瑞龙,Rui Xiong,Shiheng Liang
摘要
Superlattice engineering is a well-established strategy for reducing lattice thermal conductivity (κL), typically achieving stronger suppression perpendicular to the interfaces. In this study, we employ density functional theory and the phonon Boltzmann transport equation to investigate thermal transport in bulk SnSe2 and SnSe2/SnM2 (M = S, Te) superlattices. Counterintuitively, our results reveal that the SnSe2/SnTe2 superlattice exhibits a more pronounced in-plane κL reduction (83.68%) than that in the out-of-plane direction (77.3%), reversing the conventional out-of-plane-dominated κL suppression phenomenon. Furthermore, optical phonons rather than acoustic ones dominate the thermal transport in SnSe2/SnTe2 superlattice, contributing up to 73.5% and 64.1% to κL along the in-plane and out-of-plane directions, respectively. These anomalous behaviors are attributed to additional phonon scattering channels arising from an in-plane avoided-crossing point in the phonon dispersion, as well as the marked enhancement of in-plane acoustic phonon anharmonicity. This work not only advances the understanding of phonon transport mechanisms in superlattices but also provides a novel perspective to effectively suppress in-plane lattice thermal conductivity in layered materials.
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