材料科学
延展性(地球科学)
数字图像相关
极限抗拉强度
可塑性
拉伤
复合材料
变形(气象学)
复合数
图层(电子)
蠕动
医学
内科学
作者
Meng Huang,Guohua Fan,Lin Geng,Giacomo Cao,Yan Du,Hao Wu,T. T. Zhang,Huijun Kang,T. M. Wang,G. H. Du,Honglan Xie
摘要
Layered Ti-Al metal composite (LMC) fabricated by hot-pressing and hot-rolling process displays higher ductility than that of both components. In this paper, a combination of digital image correlation (DIC) and X-ray tomography revealed that strain delocalization and constrained crack distribution are the origin of extraordinary tensile ductility. Strain delocalization was derived from the transfer of strain partitioning between Ti and Al layer, which relieved effectively the strain localization of LMC. Furthermore, the extensive cracks of LMC were restricted in the interface due to constraint effect. Layered architecture constrained the distribution of cracks and significantly relieved the strain localization. Meanwhile, the transfer of strain partitioning and constrained crack distribution were believed to inhibit the strain localization of Ti and change the deformation mechanisms of Ti. Our finding enriches current understanding about simultaneously improving the strength and ductility by structural design.
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