English

Deep Bayesian Local Crystallography

Computational Physics 2020-12-15 v1

Abstract

The advent of high-resolution electron and scanning probe microscopy imaging has opened the floodgates for acquiring atomically resolved images of bulk materials, 2D materials, and surfaces. This plethora of data contains an immense volume of information on materials structures, structural distortions, and physical functionalities. Harnessing this knowledge regarding local physical phenomena necessitates the development of the mathematical frameworks for extraction of relevant information. However, the analysis of atomically resolved images is often based on the adaptation of concepts from macroscopic physics, notably translational and point group symmetries and symmetry lowering phenomena. Here, we explore the bottom-up definition of structural units and symmetry in atomically resolved data using a Bayesian framework. We demonstrate the need for a Bayesian definition of symmetry using a simple toy model and demonstrate how this definition can be extended to the experimental data using deep learning networks in a Bayesian setting, namely rotationally invariant variational autoencoders.

Keywords

Cite

@article{arxiv.2012.07134,
  title  = {Deep Bayesian Local Crystallography},
  author = {Sergei V. Kalinin and Mark P. Oxley and Mani Valleti and Junjie Zhang and Raphael P. Hermann and Hong Zheng and Wenrui Zhang and Gyula Eres and Rama K. Vasudevan and Maxim Ziatdinov},
  journal= {arXiv preprint arXiv:2012.07134},
  year   = {2020}
}

Comments

Combined Paper and Supplementary Information. 40 pages. 8 Figures plus 12 Supplementary figures

R2 v1 2026-06-23T20:56:07.295Z