English

Atomic Super-Resolution Tomography

Numerical Analysis 2020-07-15 v2 Materials Science Numerical Analysis Image and Video Processing Computational Physics

Abstract

We consider the problem of reconstructing a nanocrystal at atomic resolution from electron microscopy images taken at a few tilt angles. A popular reconstruction approach called discrete tomography confines the atom locations to a coarse spatial grid, which is inspired by the physical a priori knowledge that atoms in a crystalline solid tend to form regular lattices. Although this constraint has proven to be powerful for solving this very under-determined inverse problem in many cases, its key limitation is that, in practice, defects may occur that cause atoms to deviate from regular lattice positions. Here we propose a grid-free discrete tomography algorithm that allows for continuous deviations of the atom locations similar to super-resolution approaches for microscopy. The new formulation allows us to define atomic interaction potentials explicitly, which results in a both meaningful and powerful incorporation of the available physical a priori knowledge about the crystal's properties. In computational experiments, we compare the proposed grid-free method to established grid-based approaches and show that our approach can indeed recover the atom positions more accurately for common lattice defects.

Keywords

Cite

@article{arxiv.2002.00710,
  title  = {Atomic Super-Resolution Tomography},
  author = {Poulami Somanya Ganguly and Felix Lucka and Hermen Jan Hupkes and Kees Joost Batenburg},
  journal= {arXiv preprint arXiv:2002.00710},
  year   = {2020}
}

Comments

16 pages, 5 figures

R2 v1 2026-06-23T13:29:04.642Z