Dislocation-induced stop-and-go kinetics of interfacial transformations

Most engineering materials are based on multiphase microstructures produced either through the control of phase equilibria or by the fabrication of different materials as in thin-film processing. In both processes, the microstructure relaxes towards equilibrium by mismatch dislocations (or geometric...

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Bibliographic Details
Published in:Nature (London) 2022-07, Vol.607 (7920), p.708-713
Main Authors: Sun, Xianhu, Wu, Dongxiang, Zou, Lianfeng, House, Stephen D., Chen, Xiaobo, Li, Meng, Zakharov, Dmitri N., Yang, Judith C., Zhou, Guangwen
Format: Article
Language:English
Subjects:
119/118
639/301/1023/1026
639/301/299/892
639/301/357/537
639/301/930/328/2082
639/925/357/551
Copper
Copper oxides
Corrosion
Dislocation
Dislocation mobility
Fabrication
Humanities and Social Sciences
Interfaces
Kinetics
Ledges
Mass transport
MATERIALS SCIENCE
Metals and alloys
Microstructure
Misfit dislocations
multidisciplinary
Phase equilibria
Propagation
Science
Science (multidisciplinary)
Structural properties
Synthesis and processing
Thin films
Transformations
Transmission electron microscopy
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Summary:Most engineering materials are based on multiphase microstructures produced either through the control of phase equilibria or by the fabrication of different materials as in thin-film processing. In both processes, the microstructure relaxes towards equilibrium by mismatch dislocations (or geometric misfit dislocations) across the heterophase interfaces 1 – 5 . Despite their ubiquitous presence, directly probing the dynamic action of mismatch dislocations has been unachievable owing to their buried nature. Here, using the interfacial transformation of copper oxide to copper as an example, we demonstrate the role of mismatch dislocations in modulating oxide-to-metal interfacial transformations in an intermittent manner, by which the lateral flow of interfacial ledges is pinned at the core of mismatch dislocations until the dislocation climbs to the new oxide/metal interface location. Together with atomistic calculations, we identify that the pinning effect is associated with the non-local transport of metal atoms to fill vacancies at the dislocation core. These results provide mechanistic insight into solid–solid interfacial transformations and have substantial implications for utilizing structural defects at buried interfaces to modulate mass transport and transformation kinetics. Environmental transmission electron microscopy is used to reveal that mismatch dislocations modulate the interfacial transformation of copper oxide to copper metal in an intermittent manner.
ISSN:0028-0836
1476-4687
DOI:10.1038/s41586-022-04880-1