微观结构
表征(材料科学)
电子背散射衍射
材料科学
计算机科学
纳米技术
模式识别(心理学)
人工智能
冶金
作者
H.T. Vo,Peter Pinney,Matthew M. Schneider,M. Arul Kumar,Rodney J. McCabe,C.N. Tomé,Laurent Capolungo
标识
DOI:10.1016/j.mtadv.2023.100425
摘要
The advent of techniques enabling three-dimensional (3D) analysis of objects, defects, and fields has been key to discoveries and paradigm shifts in molecular biology, astrophysics, medicine, quantum physics, etc. In materials science, the 3D nature of materials microstructures remains largely hidden; leading to a fragmented understanding of microstructure-property linkages. Current tools cannot characterize large volumes of 3D microstructures at fine resolution. To this end, this study introduces a graph-theory-based framework to automatically extract 3D microstructures and statistics of electron-backscatter diffraction datasets. Further, leveraging network science, the study introduces a new approach to classify and compare microstructures; the keystone to materials taxonomy. The significance of this tool is demonstrated by studying deformation twin structures in Titanium. The study reveals extraordinarily complex and tortuous twin networks never observed via traditional two-dimensional analysis. This changes our perception of the ability of metals to withstand severe microstructure changes without failing.
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