材料科学
微观结构
极限抗拉强度
钛合金
应变硬化指数
打滑(空气动力学)
堆积
硬化(计算)
马氏体
冶金
合金
钛
复合材料
晶体孪晶
位错
可塑性
加工硬化
固溶强化
拉伤
材料的强化机理
拉伸试验
沉淀硬化
层错能
罗克韦尔标度
作者
Huizhi Peng,Yuman Zhu,Jun Wang,Jiaming Zhu,Jianwen Liu,Kai Zhang,Peter Lynch,Hamish L Fraser,Peter Hodgson,Martin Heilmaier,Nick Birbilis,Yunzhi Wang,Ai-jun Huang,Huizhi Peng,Yuman Zhu,Jun Wang,Jiaming Zhu,Jianwen Liu,Kai Zhang,Peter Lynch
标识
DOI:10.1038/s41467-025-65033-2
摘要
Strain hardening is a crucial property of metals and alloys that directly affects their mechanical processability, safe usage, and durability throughout their service life. However, titanium alloys traditionally used in structural applications often exhibit limited strain hardening, restricting their broader use. In this work, we demonstrate that by employing additive manufacturing (AM), strong strain hardening with high strength can be simultaneously achieved in a commercially available titanium alloy. These remarkable properties arise from a martensitic microstructure originated from the AM process. The microstructure is characterized by nanosized martensite plates with extremely fine triple-twinned substructures. During tensile deformation, detwinning rather than dislocation slip gradually transforms this microstructure into single-twinned lamellae with ~10 nm twin boundary spacing and internal stacking faults, necessitating progressively higher stresses and resulting in significant strain hardening.
科研通智能强力驱动
Strongly Powered by AbleSci AI