Unveiling micro-scale mechanisms of in-situ silicon alloying for tailoring mechanical properties in titanium alloys: Experiments and computational modeling

IF 11.2 1区 材料科学 Q1 MATERIALS SCIENCE, MULTIDISCIPLINARY
Sisi Tang, Li Li, Jinlong Su, Yuan Yuan, Yong Han, Jinglian Fan
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Abstract

Titanium-silicon (Ti-Si) alloy system shows significant potential for aerospace and automotive applications due to its superior specific strength, creep resistance, and oxidation resistance. For Si-containing Ti alloys, the sufficient content of Si is critical for achieving these favorable performances, while excessive Si addition will result in mechanical brittleness. Herein, both physical experiments and finite element (FE) simulations are employed to investigate the micro-mechanisms of Si alloying in tailoring the mechanical properties of Ti alloys. Four typical states of Si-containing Ti alloys (solid solution state, hypoeutectoid state, near-eutectoid state, hypereutectoid state) with varying Si content (0.3–1.2 wt.%) were fabricated via in-situ alloying spark plasma sintering. Experimental results indicate that in-situ alloying of 0.6 wt.% Si enhances the alloy's strength and ductility simultaneously due to the formation of fine and uniformly dispersed Ti5Si3 particles, while higher content of Si (0.9 and 1.2 wt.%) results in coarser primary Ti5Si3 agglomerations, deteriorating the ductility. FE simulations support these findings, highlighting the finer and more uniformly distributed Ti5Si3 particles contribute to less stress concentration and promote uniform deformation across the matrix, while agglomerated Ti5Si3 particles result in increased local stress concentrations, leading to higher chances of particle fracture and reduced ductility. This study not only elucidates the micro-mechanisms of in-situ Si alloying for tailoring the mechanical properties of Ti alloys but also aids in optimizing the design of high-performance Ti alloys.

Abstract Image

揭示原位硅合金化的微尺度机制,以定制钛合金的机械性能:实验与计算建模
钛-硅(Ti-Si)合金系统因其卓越的比强度、抗蠕变性和抗氧化性,在航空航天和汽车应用中显示出巨大的潜力。对于含硅的钛合金而言,足够的硅含量是实现这些良好性能的关键,而过量的硅添加则会导致机械脆性。本文采用物理实验和有限元(FE)模拟来研究硅合金化在定制钛合金机械性能方面的微观机制。通过原位合金化火花等离子烧结制造了四种典型的含硅钛合金状态(固溶态、低共晶态、近共晶态和超共晶态),其中硅的含量各不相同(0.3-1.2 wt.%)。实验结果表明,原位合金化 0.6 重量百分比的 Si 会形成细小且均匀分散的 Ti5Si3 颗粒,从而同时提高合金的强度和延展性;而更高的 Si 含量(0.9 和 1.2 重量百分比)会导致更粗大的原生 Ti5Si3 团聚,从而降低延展性。有限元模拟支持这些发现,突出表明更细、分布更均匀的 Ti5Si3 颗粒有助于减少应力集中并促进整个基体的均匀变形,而团聚的 Ti5Si3 颗粒会导致局部应力集中增加,从而导致颗粒断裂的几率增加和延展性降低。这项研究不仅阐明了原位 Si 合金用于定制钛合金机械性能的微观机制,还有助于优化高性能钛合金的设计。
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
Journal of Materials Science & Technology
Journal of Materials Science & Technology 工程技术-材料科学:综合
CiteScore
20.00
自引率
11.00%
发文量
995
审稿时长
13 days
期刊介绍: Journal of Materials Science & Technology strives to promote global collaboration in the field of materials science and technology. It primarily publishes original research papers, invited review articles, letters, research notes, and summaries of scientific achievements. The journal covers a wide range of materials science and technology topics, including metallic materials, inorganic nonmetallic materials, and composite materials.
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