Grain boundary migration in polycrystalline $\alpha$-Fe
Abstract
High energy x-ray diffraction microscopy was used to image the microstructure of -Fe before and after a 600 C anneal. These data were used to determine the areas, curvatures, energies, and velocities of approximately 40,000 grain boundaries. The measured grain boundary properties depend on the five macroscopic grain boundary parameters. The velocities are not correlated with the product of the mean boundary curvature and grain boundary energy, usually assumed to be the driving force. Boundary migration is made up of area changes (lateral motion) and translation (normal motion) and both contribute to the total migration. Through the lateral motion component of the migration, low energy boundaries tend to expand in area while high energy boundaries shrink, reducing the average energy through grain boundary replacement. The driving force for this process is not related to curvature and might disrupt the expected curvature-velocity relationship.
Keywords
Cite
@article{arxiv.2311.11219,
title = {Grain boundary migration in polycrystalline $\alpha$-Fe},
author = {Zipeng Xu and Yu-Feng Shen and S. Kiana Naghibzadeh and Xiaoyao Peng and Vivekanand Muralikrishnan and Siddharth Maddali and David Menasche and Amanda R. Krause and Kaushik Dayal and Robert M. Suter and Gregory S. Rohrer},
journal= {arXiv preprint arXiv:2311.11219},
year = {2023}
}
Comments
33 pages, double spaced, accepted for publication in Acta Materialia