In Situ Study on the Compression Deformation Behavior of MoNbTaVW High-Entropy Alloy

MatSciRN: Other Mechanical Properties & Deformation of Materials (Topic) Pub Date : 1900-01-01 DOI:10.2139/ssrn.3711238

Congyan Zhang, B. Yue, U. Bhandari, Oleg N Starovoytov, Yan Yang, D. Young, Jinyuan Yan, F. Hong, Shizhong Yang

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Abstract

The excellent mechanical properties of high-entropy alloys make them advanced materials in science and technology. However, the underlying mechanism of plastic deformation is not well understood. In situ experiments are urgently required to provide a fundamental understanding of the plastic deformation under high pressure. We performed in situ synchrotron x-ray diffraction experiments to study compression deformation behavior of MoNbTaVW in a radial diamond anvil cell. Our results show that the strength and ratio of the stress-to-shear modulus values are ~1.5 and 3 times of that of pure tungsten, respectively. MoNbTaVW yields at around 5 GPa and then developed a much stronger texture as compared with pure W. This work provides clear evidence that active dislocation behavior is mainly responsible for the high strength in MoNbTaVW under compression. The unique technique also opens a new avenue to investigate the in situ mechanical properties and their mechanisms in other types of alloys.

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MoNbTaVW高熵合金压缩变形行为的原位研究

高熵合金优异的力学性能使其成为先进的科学技术材料。然而，塑性变形的潜在机制尚不清楚。迫切需要现场实验来提供对高压下塑性变形的基本理解。采用同步x射线衍射实验研究了MoNbTaVW在径向金刚石砧胞中的压缩变形行为。结果表明，该合金的强度和应力剪切模量之比分别是纯钨的1.5倍和3倍。与纯钨相比，MoNbTaVW在5 GPa左右屈服，然后形成了更强的织构。这项工作提供了明确的证据，表明活动位错行为是MoNbTaVW在压缩下具有高强度的主要原因。这种独特的技术也为研究其他类型合金的原位力学性能及其机理开辟了新的途径。

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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MatSciRN: Other Mechanical Properties & Deformation of Materials (Topic)

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