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Hauptverfasser: Lan, Ling, Du, Qiang, Billinge, Simon J. L.
Format: Preprint
Veröffentlicht: 2024
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Online-Zugang:https://arxiv.org/abs/2410.21880
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author Lan, Ling
Du, Qiang
Billinge, Simon J. L.
author_facet Lan, Ling
Du, Qiang
Billinge, Simon J. L.
contents A quantitative measure of symmetry breaking is introduced that allows the quantification of which symmetries are most strongly broken due to the introduction of some kind of defect in a perfect structure. The method uses a statistical approach based on the Jensen-Shannon divergence. The measure is calculated by comparing the transformed atomic density function with its original. Software code is presented that carries the calculations out numerically using Monte Carlo methods. The behavior of this symmetry breaking measure is tested for various cases including finite size crystallites (where the surfaces break the crystallographic symmetry), atomic displacements from high symmetry positions, and collective motions of atoms due to rotations of rigid octahedra. The approach provides a powerful tool for assessing local symmetry breaking and offers new insights that can help researchers understand how different structural distortions affect different symmetry operations.
format Preprint
id arxiv_https___arxiv_org_abs_2410_21880
institution arXiv
publishDate 2024
record_format arxiv
spellingShingle A continuous symmetry breaking measure for finite clusters using Jensen-Shannon divergence
Lan, Ling
Du, Qiang
Billinge, Simon J. L.
Materials Science
Mathematical Physics
A quantitative measure of symmetry breaking is introduced that allows the quantification of which symmetries are most strongly broken due to the introduction of some kind of defect in a perfect structure. The method uses a statistical approach based on the Jensen-Shannon divergence. The measure is calculated by comparing the transformed atomic density function with its original. Software code is presented that carries the calculations out numerically using Monte Carlo methods. The behavior of this symmetry breaking measure is tested for various cases including finite size crystallites (where the surfaces break the crystallographic symmetry), atomic displacements from high symmetry positions, and collective motions of atoms due to rotations of rigid octahedra. The approach provides a powerful tool for assessing local symmetry breaking and offers new insights that can help researchers understand how different structural distortions affect different symmetry operations.
title A continuous symmetry breaking measure for finite clusters using Jensen-Shannon divergence
topic Materials Science
Mathematical Physics
url https://arxiv.org/abs/2410.21880