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Main Authors: Hall, Steven W., Minh, Porhouy, Sarupria, Sapna
Format: Preprint
Published: 2024
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Online Access:https://arxiv.org/abs/2405.09642
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author Hall, Steven W.
Minh, Porhouy
Sarupria, Sapna
author_facet Hall, Steven W.
Minh, Porhouy
Sarupria, Sapna
contents Understanding the mechanisms underlying crystal formation is crucial. For most systems, crystallization typically goes through a nucleation process that involves dynamics that happen at short time and length scales. Due to this, molecular dynamics serves as a powerful tool to study this phenomenon. Existing approaches to study the mechanism often focus analysis on static snapshots of the global configuration, potentially overlooking subtle local fluctuations and history of the atoms involved in the formation of solid nuclei. To address this limitation, we propose a methodology that categorizes nucleation pathways into reactive pathways based on the time evolution of constituent atoms. Our approach effectively captures the diverse structural pathways explored by crystallizing Lennard-Jones-like particles and solidifying Ni$_3$Al, providing a more nuanced understanding of nucleating pathways. Moreover, our methodology enables the prediction of the resulting polymorph from each reactive trajectory. This deep learning-assisted comprehensive analysis offers an alternative view of crystal nucleation mechanisms and pathways.
format Preprint
id arxiv_https___arxiv_org_abs_2405_09642
institution arXiv
publishDate 2024
record_format arxiv
spellingShingle LeaPP: Learning Pathways to Polymorphs through machine learning analysis of atomic trajectories
Hall, Steven W.
Minh, Porhouy
Sarupria, Sapna
Statistical Mechanics
Understanding the mechanisms underlying crystal formation is crucial. For most systems, crystallization typically goes through a nucleation process that involves dynamics that happen at short time and length scales. Due to this, molecular dynamics serves as a powerful tool to study this phenomenon. Existing approaches to study the mechanism often focus analysis on static snapshots of the global configuration, potentially overlooking subtle local fluctuations and history of the atoms involved in the formation of solid nuclei. To address this limitation, we propose a methodology that categorizes nucleation pathways into reactive pathways based on the time evolution of constituent atoms. Our approach effectively captures the diverse structural pathways explored by crystallizing Lennard-Jones-like particles and solidifying Ni$_3$Al, providing a more nuanced understanding of nucleating pathways. Moreover, our methodology enables the prediction of the resulting polymorph from each reactive trajectory. This deep learning-assisted comprehensive analysis offers an alternative view of crystal nucleation mechanisms and pathways.
title LeaPP: Learning Pathways to Polymorphs through machine learning analysis of atomic trajectories
topic Statistical Mechanics
url https://arxiv.org/abs/2405.09642