从第一性原理计算hfnbtizr高熵合金的相分解和强化

Shuming Chen, Ze-jun Ma, S. Qiu, Lian-Ji Zhang, Shang-zhou Zhang, Ruijie Yang, Q. Hu
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引用次数: 13

摘要

相分解对高熵合金的力学性能有重要影响。合金的超维成分空间极大地阻碍了HEA相分解的预测。在本工作中,我们建议将HEAs表示为各种伪二元合金,其组成的自由能随温度的变化可以很容易地用第一性原理方法与热力学模型相结合来计算。利用计算得到的自由能,可以构造伪二元合金的相图,并对相分解进行预测。该方法应用于体心立方(BCC)结构的Hf-Nb-Ta-Ti-Zr合金。我们预测等原子HfNbTaTiZr HEA在1298 K的临界温度下会发生相分解。HEA最有利于BCC富nbta相和富hfzr相的分解。BCC富hfzr相在低温下转变为六方密排结构(HCP)相。预测的分解相组成与实验和热计算模型吻合较好。结合固溶强化机制和析出强化机制,评价了相分解对HEA强度的影响。低退火温度下,析出强化效果强于固溶强化,高退火温度下,析出强化效果变弱。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Phase Decomposition and Strengthening in Hfnbtatizr High Entropy Alloy from First-Principles Calculations
Phase decomposition influences significantly the mechanical properties of high entropy alloys (HEAs). Prediction of the phase decomposition of HEA is greatly hindered by the hyper-dimensional composition space of the alloys. In the present work, we propose to represent the HEAs as various pseudo-binary alloys of which the temperature dependent free energies as functions of compositions may be readily calculated by using first-principles methods in combination with thermodynamic models. With the calculated free energies, the phase diagrams of the pseudo-binary alloys may be constructed and the phase decomposition can be predicted. This procedure is applied to Hf-Nb-Ta-Ti-Zr alloy with body-centered cubic (BCC) structure. We predict that the equiatomic HfNbTaTiZr HEA suffers from phase decomposition below critical temperature of 1298 K. The HEA decomposes most favorably to BCC NbTa-rich and HfZr-rich phases. The BCC HfZr-rich phase transfers to a hexagonal close-packed structure (HCP) phase at low temperature. The predicted compositions of the decomposed phases are in good agreement with experiment and Thermal-Calc modeling. Furthermore, the effect of the phase decomposition on the strength of the HEA is evaluated by considering the solid-solution and precipitation strengthening mechanisms. The precipitation strengthening effect is stronger than the solid-solution strengthening at the low annealing temperature but becomes weaker at high annealing temperature.
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