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标题：Ab initio predictions of structure and physical properties of the Zr2GaC and Hf2GaC MAX phases under pressure
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作者：Muhammad Waqas Qureshi ; Xinxin Ma ; Guangze Tang 等
期刊名称：Scientific Reports
电子版ISSN：2045-2322
出版年度：2021
卷号：11
期号：1
页码：3260
DOI：10.1038/s41598-021-82402-1
出版社：Springer Nature
摘要：The electronic structure, structural stability, mechanical, phonon, and optical properties of Zr 2 GaC and Hf 2 GaC MAX phases have been investigated under high pressure using first-principles calculations. Formation enthalpy of competing phases, elastic constants, and phonon calculations revealed that both compounds are thermodynamically, mechanically, and dynamically stable under pressure. The compressibility of Zr 2 GaC is higher than that of Hf 2 GaC along the c-axis, and pressure enhanced the resistance to deformation. The electronic structure calculations reveal that M 2 GaC is metallic in nature, and the metallicity of Zr 2 GaC increased more than that of Hf 2 GaC at higher pressure. The mechanical properties, including elastic constants, elastic moduli, Vickers hardness, Poisson's ratio anisotropy index, and Debye temperature, are reported with fundamental insights. The elastic constants C 11 and C 33 increase rapidly compared with other elastic constants with an increase in pressure, and the elastic anisotropy of Hf 2 GaC is higher than that of the Zr 2 GaC. The optical properties revealed that Zr 2 GaC and Hf 2 GaC MAX phases are suitable for optoelectronic devices in the visible and UV regions and can also be used as a coating material for reducing solar heating at higher pressure up to 50 GPa.
其他摘要：Abstract The electronic structure, structural stability, mechanical, phonon, and optical properties of Zr 2 GaC and Hf 2 GaC MAX phases have been investigated under high pressure using first-principles calculations. Formation enthalpy of competing phases, elastic constants, and phonon calculations revealed that both compounds are thermodynamically, mechanically, and dynamically stable under pressure. The compressibility of Zr 2 GaC is higher than that of Hf 2 GaC along the c-axis, and pressure enhanced the resistance to deformation. The electronic structure calculations reveal that M 2 GaC is metallic in nature, and the metallicity of Zr 2 GaC increased more than that of Hf 2 GaC at higher pressure. The mechanical properties, including elastic constants, elastic moduli, Vickers hardness, Poisson’s ratio anisotropy index, and Debye temperature, are reported with fundamental insights. The elastic constants C 11 and C 33 increase rapidly compared with other elastic constants with an increase in pressure, and the elastic anisotropy of Hf 2 GaC is higher than that of the Zr 2 GaC. The optical properties revealed that Zr 2 GaC and Hf 2 GaC MAX phases are suitable for optoelectronic devices in the visible and UV regions and can also be used as a coating material for reducing solar heating at higher pressure up to 50 GPa.