应变可调布丁型SnP3单层带结构及热电性能

Shasha Wei, Cong Wang, S. Fan, G. Gao
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引用次数: 13

摘要

最近的研究表明,当层状体GeP3和SnP3仅限于单层或双层时,金属到半导体的转变很有趣,并且单层SnP3被预测具有高载流子迁移率和有前途的热电性能。本文研究了双轴应变对SnP3单层电子和热电性能的影响。我们的第一性原理计算结合玻尔兹曼输运理论表明,SnP3单层具有布丁霉型价带结构,具有较大的p型塞贝克系数和较高的p型功率因数。压缩双轴应变可以减小能隙,提高金属丰度。而拉伸双轴应变增大了能隙,增大了n型塞贝克系数,降低了n型电导率。虽然在拉伸双轴应变下,由于声子模式的最大频率增加和声子群速度增加,晶格导热系数增大,但仍然很低,在室温下,在6%的拉伸双轴应变下,晶格导热系数仅为3.1 W/(mK)。因此,即使在6%的拉伸应变下,SnP3单层也具有较低的晶格导热系数,是一种良好的热电材料,且拉伸应变有利于n型塞贝克系数的提高。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Strain tunable pudding-mold-type band structure and thermoelectric properties of SnP3 monolayer
Recent studies indicated the interesting metal-to-semiconductor transition when layered bulk GeP3 and SnP3 are restricted to the monolayer or bilayer, and SnP3 monolayer has been predicted to possess high carrier mobility and promising thermoelectric performance. Here, we investigate the biaxial strain effect on the electronic and thermoelectric properties of SnP3 monolayer. Our first-principles calculations combined with Boltzmann transport theory indicate that SnP3 monolayer has the pudding-mold-type valence band structure, giving rise to a large p-type Seebeck coefficient and a high p-type power factor. The compressive biaxial strain can decrease the energy gap and result in the metallicity. In contrast, the tensile biaxial strain increases the energy gap, and increases the n-type Seebeck coefficient and decreases the n-type electrical conductivity. Although the lattice thermal conductivity becomes larger at a tensile biaxial strain due to the increased maximum frequency of the acoustic phonon modes and the increased phonon group velocity, it is still low, only e.g. 3.1 W/(mK) at room temperature with the 6% tensile biaxial strain. Therefore, SnP3 monolayer is a good thermoelectric material with low lattice thermal conductivity even at the 6% tensile strain, and the tensile strain is beneficial to the increase of the n-type Seebeck coefficient.
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