Facile Route to Implement Transformation Strengthening in Lightweight Alloys

MatSciRN: Process & Device Modeling (Topic) Pub Date : 2021-01-01 DOI:10.2139/ssrn.3886367

G. Zhao, Xin Xu, D. Dye, P. Rivera-Díaz-del-Castillo, N. Petrinic

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Abstract

Developing lighter, stronger and more ductile aerospace metallic materials is in demand for energy efficiency strategies. Alloys with twinning-induced plasticity (TWIP) and/or transformation-induced plasticity (TRIP) effects have been exploited to defeat the conflict of strength versus ductility, yet very few if any physically informed methods exist to address the complex interactions between transitions. Here we report a facile route to deploy transformation-mediated strengthening in lightweight Ti alloys, which particularly focuses on the controlled activation of TRIP and TWIP via a mechanism-driven modelling approach. New alloys were comparatively developed and presented notable resistances to strain localisation, but interestingly through distinct mechanical characteristics. Specifically, extraordinary strain-hardening rate with a peak value of 2.4 GPa was achieved in Ti-10Mo-5Nb (wt.%), resulting from the synergetic activation of hierarchical transformations. A model integrating TRIP and TWIP was applied to understand the interplays between the transition mechanisms that individually contribute to strength and uniform elongation.

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实现轻量化合金相变强化的捷径

开发更轻、更强、更具延展性的航空航天金属材料是能源效率战略的需求。具有孪生诱导塑性(TWIP)和/或相变诱导塑性(TRIP)效应的合金已经被用来克服强度与延性的冲突，但很少有物理上的方法可以解决相变之间复杂的相互作用。在这里，我们报告了一种在轻质钛合金中部署转化介导强化的简单途径，特别是通过机制驱动的建模方法来控制TRIP和TWIP的激活。新合金相对发达，表现出显著的抗应变局域化能力，但有趣的是，其机械特性也不同。具体来说，在Ti-10Mo-5Nb中，由于分层转变的协同激活，实现了异常的应变硬化速率，峰值为2.4 GPa (wt.%)。一个整合了TRIP和TWIP的模型被应用于理解各自有助于强度和均匀伸长率的过渡机制之间的相互作用。

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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