高压下HfSi2的声子、弹性和热力学性质的第一性原理研究

IF 1.1 4区工程技术 Q4 Engineering

High Temperatures-high Pressures Pub Date : 2022-01-01 DOI:10.32908/hthp.v51.1193

Jinjuan Sun, Yu-Long Han, X. Yao

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引用次数: 1

摘要

基于密度泛函理论和Debye准谐波近似，计算了高压对正交相HfSi2的声子、电子、弹性和热力学性质的影响。计算结果表明，当压力在0 ~ 50 GPa范围内时，HfSi2动态稳定，声子谱上不存在虚频率，但当压力大于70 GPa时，声子谱X附近出现虚频率，发生结构相变。我们预测HfSi2的能带结构为金属结构。随着压力的增大，弹性常数Cij增大，符合Born准则。在一定压力范围内机械稳定。同时，B、E、G和B/G均随压力的增大而增大。这说明适当改变压力可以改变材料的塑性和韧性。德拜温度和声速随压力的增加而线性增加，因此压力可以提高材料的弹性、硬度、熔点和比热。

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First-principle study of phonon, elastic and thermodynamic properties of HfSi2 under high pressure

Based on density functional theory and Debye quasi-harmonic approximation, the effects of high pressure on the phonon, electronic, elastic, and thermodynamic properties of the orthogonal phase HfSi2 have been calculated. The calculated results show that when the pressure is within the pressure range of 0 GPa to 50 GPa, HfSi2 is dynamically stable, and there is no virtual frequency on the phonon spectrum, but when the pressure is greater than 70 GPa, virtual frequencies appear near the phonon spectrum X, A structural phase change occurred. We predict that the band structure of HfSi2 is metallic. As the pressure increases, the elastic constant Cij increases and conforms to the Born criterion. It is mechanically stable in a certain pressure range. At the same time, B, E, G, and B/G all increase with the increase of pressure. This shows that changing the pressure appropriately can change the ductility and toughness of the material. The Debye temperature and sound velocity increase linearly with the increase of pressure, so the elasticity, hardness, melting point, and specific heat of the material can be improved by pressure.

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来源期刊

High Temperatures-high Pressures THERMODYNAMICS-MECHANICS

CiteScore

1.00

自引率

9.10%

发文量

期刊介绍： High Temperatures – High Pressures (HTHP) is an international journal publishing original peer-reviewed papers devoted to experimental and theoretical studies on thermophysical properties of matter, as well as experimental and modelling solutions for applications where control of thermophysical properties is critical, e.g. additive manufacturing. These studies deal with thermodynamic, thermal, and mechanical behaviour of materials, including transport and radiative properties. The journal provides a platform for disseminating knowledge of thermophysical properties, their measurement, their applications, equipment and techniques. HTHP covers the thermophysical properties of gases, liquids, and solids at all temperatures and under all physical conditions, with special emphasis on matter and applications under extreme conditions, e.g. high temperatures and high pressures. Additionally, HTHP publishes authoritative reviews of advances in thermophysics research, critical compilations of existing data, new technology, and industrial applications, plus book reviews.