Introduction
The pursuit of new technologies for cleaner energy conversion requires new generation of advanced metallic alloys and ceramics that can operate safely at extreme environments (high temperature, high presure, strong radiation, etc.). The properties of these structural and functional materials are strongly influenced by the defects including surfaces, grain boundaries, and interfaces, which depend on materials synthesis and processing. Understanding their atomic structures and how they influence the physical properties is the key to optimizing materials to meet the needs of advanced energy applications. Recent years have seen a rapid growth of evidence suggesting that grain boundaries can exist in multiple states or phases and exhibit first-order transitions, marked by discontinuous changes in properties like segregation, mobility, cohesive strength and sliding resistance. These discontinuous transitions were observed in isolated bicrystals with a single well-defined grain boundary as well as in polycrystalline samples with many different grain boundaries.
Selected Applications
Relevant works
-
Zhu S-C, Yan X-Z, Liu J., Oganov A.R., Zhu Q. (2020). A Revisited Mechanism of the Graphite-to-Diamond Transition at High Temperature. Matter 3, 1–15. (PDF)
-
Frolov T, Setyawan W, Kurtz R, Marian J, Oganov AR, Rudd RE, Zhu Q, (2018) Grain boundary phases in bcc metals Nano Scale, 10, 8253-8268 (pdf)
-
Zhu Q, Samanta A, Li, B-X, Rudd, R.E., Frolov, T. (2018) Predicting phase behavior of grain boundaries with evolutionary search and machine learning. Nature Communication, 9, 467
-
Frolov T, Zhu Q, Oppelstrup T, Marian J, Rudd RE, (2018) Structures and transitions in bcc tungsten grain boundaries and their role in the absorption of point defects Acta Mater., 159, 123-134 (pdf)