Interlayer Engineering of Lattice Dynamics and Elastic Constants of 2D Layered Nanomaterials under Pressure

Guoshuai Du, Lili Zhao, Shuchang Li, Jing Huang, Susu Fang, Wuxiao Han, Jiayin Li, Yubing Du, Jiaxin Ming, Tiansong Zhang, Jun Zhang, Jun Kang, Xiaoyan Li, Weigao Xu, Yabin Chen
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Abstract

Interlayer coupling in two-dimensional (2D) layered nanomaterials can provide us novel strategies to evoke their superior properties, such as the exotic flat bands and unconventional superconductivity of twisted layers, the formation of moir\'e excitons and related nontrivial topology. However, to accurately quantify interlayer potential and further measure elastic properties of 2D materials remains vague, despite significant efforts. Herein, the layer-dependent lattice dynamics and elastic constants of 2D nanomaterials have been systematically investigated via pressure-engineering strategy based on ultralow frequency Raman spectroscopy. The shearing mode and layer-breathing Raman shifts of MoS2 with various thicknesses were analyzed by the linear chain model. Intriguingly, it was found that the layer-dependent d{\omega}/dP of shearing and breathing Raman modes display the opposite trends, quantitatively consistent with our molecular dynamics simulations and density functional theory calculations. These results can be generalized to other van der Waals systems, and may shed light on the potential applications of 2D materials in nanomechanics and nanoelectronics.
压力下二维层状纳米材料晶格动力学和弹性常数的层间工程学
二维(2D)层状纳米材料中的层间耦合可以为我们提供唤起其优异特性的新策略,例如扭曲层的奇异平带和非常规超导性、moir\'e 激子的形成以及相关的非难拓扑。然而,尽管做出了巨大努力,但如何准确量化层间电位并进一步测量二维材料的弹性特性仍然是一个模糊的问题。本文基于超低频拉曼光谱,通过压力工程策略系统地研究了二维纳米材料的层间晶格动力学和弹性常数。通过线性链模型分析了不同厚度 MoS2 的剪切模式和层呼吸拉曼位移。有趣的是,我们发现剪切拉曼模式和呼吸拉曼模式的层依赖性 d{\omega}/dP 显示出相反的趋势,这与我们的分子动力学模拟和密度泛函理论计算结果在定量上是一致的。这些结果可以推广到其他范德华系统,并可能揭示二维材料在纳米力学和纳米电子学中的潜在应用。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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