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Observations of unexpected grain boundary migration in SrTiO3

Vivekanand Muralikrishnan, He Liu, Lin Yang, Bryan Conry, Christopher J. Marvel, Martin P. Harmer, Gregory S. Rohrer, Michael Tonks, Robert M. Suter, Carl E. Krill, Amanda R. Krause

2022Scripta Materialia37 citationsDOIOpen Access PDF

Abstract

High-energy x-ray diffraction microscopy (HEDM) nondestructively maps microstructures in 3D, allowing for the same grains and boundaries to be tracked over time during annealing experiments. Here, HEDM was applied to observe grain growth in strontium titanate. These results are compared to a 3D isotropic grain growth simulation that starts from the same initial microstructure to identify potentially unknown grain boundary migration mechanisms. During the simulation, grain growth behaves as expected: the change in grain volume is correlated with the number of neighbors, and the grain boundary velocity is correlated with its local curvature. Experimentally, however, flat boundaries were found to move faster than curved boundaries, and 37% of all measured boundaries move in the direction opposite to their curvature. These unexpected observations suggest that, in materials with anisotropic grain boundary properties, mechanisms other than curvature-driven boundary migration play a role in the minimization of interfacial energy.

Topics & Concepts

Grain boundaryMaterials scienceGrain boundary strengtheningGrain growthCurvatureIsotropyMicrostructureAnisotropyGrain boundary diffusion coefficientAnnealing (glass)Boundary (topology)DiffractionStrontium titanateAbnormal grain growthCrystallographyGeometryCondensed matter physicsComposite materialOpticsNanotechnologyMathematical analysisPhysicsThin filmMathematicsChemistryAdvanced Mathematical Modeling in EngineeringComposite Material MechanicsMicrostructure and mechanical properties
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