Litcius/Paper detail

Matching crystal structures atom-to-atom

Félix Therrien, Peter Graf, Vladan Stevanović

2020The Journal of Chemical Physics25 citationsDOIOpen Access PDF

Abstract

Finding an optimal match between two different crystal structures underpins many important materials science problems, including describing solid-solid phase transitions and developing models for interface and grain boundary structures. In this work, we formulate the matching of crystals as an optimization problem where the goal is to find the alignment and the atom-to-atom map that minimize a given cost function such as the Euclidean distance between the atoms. We construct an algorithm that directly solves this problem for large finite portions of the crystals and retrieves the periodicity of the match subsequently. We demonstrate its capacity to describe transformation pathways between known polymorphs and to reproduce experimentally realized structures of semi-coherent interfaces. Additionally, from our findings, we define a rigorous metric for measuring distances between crystal structures that can be used to properly quantify their geometric (Euclidean) closeness.

Topics & Concepts

Matching (statistics)Metric (unit)Euclidean geometryMathematicsTransformation (genetics)AlgorithmBoundary (topology)Construct (python library)Function (biology)Phase (matter)Crystal (programming language)Phase transitionEuclidean distanceTopology (electrical circuits)Metric spaceInterface (matter)Computer scienceOptimization problemCrystal structureGeometric transformationCrystal structure predictionSet (abstract data type)Mathematical optimizationBoundary value problemData structureComputational geometryMachine Learning in Materials ScienceAdvanced Electron Microscopy Techniques and ApplicationsMicrostructure and mechanical properties