A strategy for designing Ti-based in-situ bulk metallic glass composites with tailored structural metastability using conventional titanium alloys

Dingming Liu, Yufan Li, Hongxi Deng, Yan Liu, Wenting Zhang, Lei Li, Xujin Ge, Huiyuan Zheng, Wenfeng Liu, Zhengwang Zhu, Haifeng Zhang
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Abstract

The metastability of the dendritic phase is crucial in determining the mechanical properties and mechanisms of the Ti-based dendrite-reinforced bulk metallic glass composites (BMGCs). However, tailoring the metastability effectively remains challenging. In this study, we propose a straightforward and effective strategy to tailor the dendrites composition and metastability using conventional Titanium alloys. Initially, six common Titanium alloys with increasing content of β-stabilizing elements such as Ti, Ti–6Al–4V, Ti–13Nb–13Zr, Ti–15Mo, Ti–12Mo–6Zr–2Fe and Ti-4.5Fe-6.8Mo-1.5Al were selected. Subsequently, a series of dendrite-reinforced BMGCs denoted as T1-T6 were designed by alloying these Titanium alloys with a specific amorphous alloy. It was found that the microstructure, stability and mechanical behaviors of these composites change significantly as the content of β-stabilizing elements in the dendritic phase increases monotonically. Based on their microstructure and mechanical behaviors, these composites can be classified into three categories: T1, T2 and T3, T4-T6. The T1 alloy exhibits brittle deformation characteristics due to the significantly higher elastic modulus of the dendritic phase. In contrast, the T2 and T3 alloys demonstrate good tensile plasticity and remarkable work-hardening ability, attributed to the metastable β phase undergoing stress-induced phase transformation during deformation. On the other hand, the T4-T6 alloys, consisting of stable β phase, deform via dislocation slip, resulting in a higher yielding stress and compression plasticity. The composition design strategy presented in this study, along with the correlation between mechanical behaviors and dendrite stability, may offer a novel perspective for the development of Ti-based dendrite-reinforced BMGCs.
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利用传统钛合金设计具有定制结构易变性的钛基原位块体金属玻璃复合材料的策略
树枝状相的蜕变性对于决定钛基树枝状强化块状金属玻璃复合材料(BMGC)的机械性能和机理至关重要。然而,有效地定制瞬变性仍然是一项挑战。在本研究中,我们提出了一种直接有效的策略,利用传统钛合金来定制树枝晶的成分和析出性。首先,我们选择了六种β稳定元素含量不断增加的普通钛合金,如 Ti、Ti-6Al-4V、Ti-13Nb-13Zr、Ti-15Mo、Ti-12Mo-6Zr-2Fe 和 Ti-4.5Fe-6.8Mo-1.5Al。随后,通过将这些钛合金与特定的非晶合金进行合金化,设计出了一系列树枝状强化 BMGC,命名为 T1-T6。研究发现,随着树枝状相中 β 稳定元素含量的单调增加,这些复合材料的微观结构、稳定性和力学性能会发生显著变化。根据其微观结构和机械性能,这些复合材料可分为三类:T1、T2 和 T3,即 T4-T6。由于树枝状相的弹性模量明显较高,T1 合金表现出脆性变形特征。相比之下,T2 和 T3 合金则表现出良好的拉伸塑性和显著的加工硬化能力,这归功于在变形过程中发生应力诱导相变的可转移 β 相。另一方面,T4-T6 合金由稳定的 β 相组成,通过位错滑移发生变形,从而产生较高的屈服应力和压缩塑性。本研究提出的成分设计策略以及机械行为与树枝晶稳定性之间的相关性,可为开发钛基树枝晶增强 BMGC 提供新的视角。
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