First-Principles study of structural, elastic and electronic properties for the KT-GaBP2 semiconductor under pressure
Autor: | Guang-Hua Liu, Sheng-Hui Qian, Xin-Xin Ding, Yan-Tong Bian |
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Rok vydání: | 2021 |
Předmět: |
010302 applied physics
Phase transition Materials science Condensed matter physics Band gap Mechanical Engineering 02 engineering and technology 021001 nanoscience & nanotechnology Condensed Matter Physics 01 natural sciences Statistics::Computation symbols.namesake Thermal conductivity Mechanics of Materials 0103 physical sciences symbols General Materials Science Deformation (engineering) 0210 nano-technology Anisotropy Single crystal Elastic modulus Debye model |
Zdroj: | Materials Science in Semiconductor Processing. 123:105585 |
ISSN: | 1369-8001 |
DOI: | 10.1016/j.mssp.2020.105585 |
Popis: | The structural, elastic and electronic properties of KT-GaBP 2 under pressure ranging from 0 to 70 GPa were investigated by using density functional theory. The elastic stiffness constants were calculated under different pressures and found that the single crystal KT-GaBP 2 is elastically stable in the range from 0 to 70 GPa, and afterwards becomes unstable. It can be inferred that the phase transition may occur in the range of 70 ∼ 80 GPa. The universal anisotropy index of single crystal KT-GaBP 2 , as well as the elastic moduli and Debye temperature for the polycrystal KT-GaBP 2 were calculated under different pressures, and the effect of pressure on the elastic properties was studied further. It is found that the single crystal KT-GaBP 2 is elastically anisotropic and that the anisotropy increases monotonically with increasing pressure. The polycrystal KT-GaBP 2 inclines to resist better volume compression than shape deformation, and it will possess a best thermal conductivity under a certain pressure value within the range of 25 ∼ 35 GPa. Finally, the electronic properties of KT-GaBP 2 induced by pressure were studied and found that the energy gap decreases monotonically with increasing pressure. Furthermore, the direct energy gap changes into an indirect one as the pressure up to about 70 GPa. |
Databáze: | OpenAIRE |
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