Elemental segregation inhibits hydrogen embrittlement in aluminium alloys

Advanced Powder Materials Pub Date : 2023-04-01 DOI:10.1016/j.apmate.2022.100099

Jun Hui , Biao Wang , Jiapeng Chen , Xiaoyong Zhang

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引用次数: 1

Abstract

In this study, we performed first-principles calculations to determine the effects of four metallic solutes (Y, Zr, Mg, and Zn) on the hydrogen embrittlement (HE) of aluminum alloys with the Σ5(210) grain boundary (GB). The segregation energy, associated segregation concentration, and binding energy of these solutes were examined to identify their states. Moreover, the ability of the aforementioned solutes to inhibit or promote HE in the aforementioned alloys through GB energy, free surface energy, and adhesion was investigated. The Griffith and Rice–Wang–Scheiber models were used to determine the effect of nonequilibrium concentration on adhesion. Tensile tests were performed using the uniaxial strain loading method to determine the ultimate tensile strength and GB elongation of the considered alloys. The mechanism of HE inhibition by the four solutes was investigated by examining the charge density, Bader charge, and crystal orbital Hamiltonian population of the alloys. Finally, the calculation results of this study were validated through experiments.

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元素偏析抑制铝合金中的氢脆

在本研究中，我们进行了第一性原理计算，以确定四种金属溶质（Y、Zr、Mg和Zn）对具有∑5（210）晶界（GB）的铝合金的氢脆（HE）的影响。检测了这些溶质的偏析能、相关偏析浓度和结合能，以确定它们的状态。此外，研究了上述溶质通过GB能、自由表面能和粘附力抑制或促进上述合金中HE的能力。Griffith和Rice–Wang–Scheiber模型用于确定非平衡浓度对粘附的影响。使用单轴应变加载法进行拉伸试验，以确定所考虑合金的极限拉伸强度和GB伸长率。通过检测合金的电荷密度、Bader电荷和晶体轨道哈密顿布居，研究了四种溶质对HE的抑制机制。最后，通过实验验证了本研究的计算结果。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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来源期刊

Advanced Powder Materials

CiteScore

33.30

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0.00%

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