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GeS单层中应变增强的热电性能。

Strain-Enhanced Thermoelectric Performance in GeS Monolayer.

作者信息

Ruan Xinying, Xiong Rui, Cui Zhou, Wen Cuilian, Ma Jiang-Jiang, Wang Bao-Tian, Sa Baisheng

机构信息

Key Laboratory of Eco-Materials Advanced Technology, College of Materials Science and Engineering, Fuzhou University, Fuzhou 350100, China.

Institute of High Energy Physics, Chinese Academy of Sciences (CAS), Beijing 100049, China.

出版信息

Materials (Basel). 2022 Jun 6;15(11):4016. doi: 10.3390/ma15114016.

DOI:10.3390/ma15114016
PMID:35683314
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC9182024/
Abstract

Strain engineering has attracted extensive attention as a valid method to tune the physical and chemical properties of two-dimensional (2D) materials. Here, based on first-principles calculations and by solving the semi-classical Boltzmann transport equation, we reveal that the tensile strain can efficiently enhance the thermoelectric properties of the GeS monolayer. It is highlighted that the GeS monolayer has a suitable band gap of 1.50 eV to overcome the bipolar conduction effects in materials and can even maintain high stability under a 6% tensile strain. Interestingly, the band degeneracy in the GeS monolayer can be effectually regulated through strain, thus improving the power factor. Moreover, the lattice thermal conductivity can be reduced from 3.89 to 0.48 W/mK at room temperature under 6% strain. More importantly, the optimal ZT value for the GeS monolayer under 6% strain can reach 0.74 at room temperature and 0.92 at 700 K, which is twice its strain-free form. Our findings provide an exciting insight into regulating the thermoelectric performance of the GeS monolayer by strain engineering.

摘要

应变工程作为一种调节二维(2D)材料物理和化学性质的有效方法,已引起广泛关注。在此,基于第一性原理计算并通过求解半经典玻尔兹曼输运方程,我们揭示了拉伸应变可有效增强GeS单层的热电性能。值得注意的是,GeS单层具有1.50 eV的合适带隙,可克服材料中的双极传导效应,甚至在6%的拉伸应变下仍能保持高稳定性。有趣的是,GeS单层中的能带简并可通过应变有效地调节,从而提高功率因子。此外,在6%应变下,室温下晶格热导率可从3.89降低至0.48 W/mK。更重要的是,GeS单层在6%应变下的最佳ZT值在室温下可达0.74,在700 K时可达0.92,是其无应变形式的两倍。我们的研究结果为通过应变工程调节GeS单层的热电性能提供了令人兴奋的见解。

https://cdn.ncbi.nlm.nih.gov/pmc/blobs/0258/9182024/3cfe48c1c213/materials-15-04016-g001.jpg

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