耐火材料(MoW) 85 Zr 7.5(TaTi) 7.5高熵合金的假弹性变形

A. Sharma, P. Singh, T. Kirk, V. Levitas, P. Liaw, G. Balasubramanian, R. Arróyave, Duane D. Johnson
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引用次数: 2

摘要

密度泛函理论方法支持的相图对于设计高熵合金(HEAs)至关重要。我们结合相图计算(CALPHAD)和密度泛函理论的结果,对耐火材料  quary (MoW)xZry(tti)1-x-y HEAs进行了相和性质分析,并辅之以 分子动力学(MD)模拟。我们的分析表明,该五元体系的富mo - w区具有稳定的单相体心立方(bcc)。(MoW)85Zr7.5(tti)7.5是基于温度依赖的calphhad相图分析和MD预测的弹性行为,揭示了该难熔HEA的孪晶辅助伪弹性行为。孪晶是一种基本的变形机制,它与晶体固体中的位错滑移相竞争。该合金在单轴状态下表现出相同的循环变形特征。加载,即伪弹性在加载方向上是各向同性的。此外,温度从77 K升高到1500 K可以增强加载-卸载循环中的弹性应变恢复,从而可能控制和调整伪弹性行为。
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Pseudoelastic Deformation in Refractory (MoW) 85 Zr 7.5(TaTi) 7.5 High-Entropy Alloy
Phase diagrams supported by density functional theory methods can be crucial for designing high-entropy alloys (HEAs). We present phase and property analysis of refractory quinary (MoW)xZry(TaTi)1-x-y HEAs from combined Calculation of Phase Diagram (CALPHAD) and density-functional theory results, supplemented by molecular dynamics (MD) simulations. Our analysis indicates a Mo-W-rich region of this quinary system has a stable single-phase body-centered-cubic (bcc). The (MoW)85Zr7.5(TaTi)7.5 was down-selected based on temperature-dependent CALPHAD phase diagram analysis and MD predicted elastic behavior that reveals twinning-assisted pseudoelastic behavior in this refractory HEA. While mostly unexplored in bcc crystals, twinning is a fundamental deformation mechanism that competes against dislocation slip in crystalline solids. This alloy shows identical cyclic deformation characteristics during uniaxial <100> loading, i.e., the pseudoelasticity is isotropic in loading direction. Additionally, a temperature increase from 77 to 1,500 K enhances the elastic strain recovery in load-unload cycles, offering possibly control to tune the pseudoelastic behavior.
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