First-Principles-Based Structural and Mechanical Properties of Al<sub>3</sub>Ni Under High Pressure

First-Principles-Based Structural and Mechanical Properties of Al<sub>3</sub>Ni Under High Pressure

The structural, elastic, and thermal characteristics within the 0–30 GPa pressure range of Al<sub>3</sub>Ni intermetallic compounds were extensively studied using first-principles computational techniques. Using structural optimization, lattice parameters and the variation in volume vari...

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Bibliographic Details
Main Authors: Chuncai Xiao, Baiyuan Yang, Zhangli Lai, Zhiquan Chen, Huaiyang Yang, Hui Wang, Yunzhi Zhou, Xianshi Zeng
Format: Article
Language:English
Published: MDPI AG 2024-12-01
Series:Crystals
Subjects:
high-pressure properties
first-principles calculations
Al<sub>3</sub>Ni
elastic constants
Online Access:https://www.mdpi.com/2073-4352/15/1/3
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Summary:The structural, elastic, and thermal characteristics within the 0–30 GPa pressure range of Al<sub>3</sub>Ni intermetallic compounds were extensively studied using first-principles computational techniques. Using structural optimization, lattice parameters and the variation in volume variation under diverse pressures were determined, and the trends in their structural alteration with pressure were identified. The computed elastic constants validate the mechanical stability of Al<sub>3</sub>Ni within the applied pressure range and show that its compressive stiffness and shear resistance increase rapidly with increasing pressure. The Cauchy pressure variation implies that the metallic nature of Al<sub>3</sub>Ni increases gradually with increasing pressure. Moreover, through analysis of Poisson’s ratio, the anisotropy factor, and the sound velocity, we ascertained that pressure attenuates the anisotropic attributes of the material, and Al<sub>3</sub>Ni exhibits more pronounced isotropic characteristics and mechanical homogeneity under high-pressure conditions. The substantial increase in the Debye temperature further suggests that high pressure fortifies the lattice dynamic rigidity of the material. This current research systematically elucidated the stability of Al<sub>3</sub>Ni under high-pressure conditions and the law of the transformation of it mechanical behavior, providing a theoretical foundation for its application under extreme circumstances.
ISSN:2073-4352

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