材料科学
晶体孪晶
变形机理
复合材料
可塑性
透射电子显微镜
极限抗拉强度
冶金
金属
位错
微观结构
机制(生物学)
压力(语言学)
变形(气象学)
断裂(地质)
材料的强化机理
延展性(地球科学)
晶界
断口学
表征(材料科学)
结构材料
铰链
作者
Jinqiao Liu,Ranming Niu,Ji Gu,Ying Liu,Song Ni,Julie M. Cairney,Min Song,Mai Yiu-Wing,Ting Zhu,Xiaozhou Liao
标识
DOI:10.1016/j.actamat.2025.121880
摘要
The increasing demand for high-performance miniaturised devices has sparked extensive interest in enhancing the mechanical properties of micro- and nano-sized materials. Deformation twinning, a fundamental mechanism known for enabling strength–ductility synergy in bulk materials, has emerged as a potential strengthening strategy for small-scale systems. However, the relationship between twinning behaviour and the mechanical performance of small-sized materials remains poorly understood. This study employs quantitative in-situ tensile straining transmission electron microscopy combined with comprehensive microstructural characterisation to investigate the effects of three critical aspects of twinning behaviour on mechanical performance in small-sized face-centred cubic metallic materials: twin density, twin–twin interactions, and modes of twin boundary motion. The findings reveal that: (1) increasing twin density improves ductility of small-sized samples, but this effect hinges on the absence of stress-concentration sites; (2) twin–twin interactions, caused by their intersecting behaviour, induce stress concentration and promote necking, resulting in a distinct fracture mechanism compared to single-system twinning; and (3) twin-boundary sliding, in contrast to twin-boundary migration, leads to highly localised deformation, pronounced softening, and significantly reduced ductility. These results provide important insights into the structural design of small-sized single-crystalline materials where twinning-induced plasticity is a dominant deformation mechanism.
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