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Main Authors: Si, Wei, Li, Shifeng, Zhang, Pingwen, Shi, An-Chang, Jiang, Kai
Format: Preprint
Published: 2024
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Online Access:https://arxiv.org/abs/2409.11830
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author Si, Wei
Li, Shifeng
Zhang, Pingwen
Shi, An-Chang
Jiang, Kai
author_facet Si, Wei
Li, Shifeng
Zhang, Pingwen
Shi, An-Chang
Jiang, Kai
contents Interparticle interactions with multiple length scales play a pivotal role in the formation and stability of quasicrystals. Choosing a minimal set of length scales to stabilize a given quasicrystal is a challenging problem. To address this challenge, we propose an intelligent screening method (ISM) to design a Landau theory with a minimal number of length scales -- referred to as the minimal Landau theory -- that includes only the essential length scales necessary to stabilize quasicrystals. Based on a generalized multiple-length-scale Landau theory, ISM first evaluates various spectral configurations of candidate structures under a hard constraint. It then identifies the configuration with the lowest free energy. Using this optimal configuration, ISM calculates phase diagrams to explore the thermodynamic stability of desired quasicrystals. ISM can design a minimal Landau theory capable of stabilizing the desired quasicrystals by incrementally increasing the number of length scales. Our application of ISM has not only confirmed known behaviors in 10- and 12-fold quasicrystals but also led to a significant prediction that quasicrystals with 8-, 14-, 16-, and 18-fold symmetry could be stable within three-length-scale Landau models.
format Preprint
id arxiv_https___arxiv_org_abs_2409_11830
institution arXiv
publishDate 2024
record_format arxiv
spellingShingle Designing a minimal Landau theory to stabilize desired quasicrystals
Si, Wei
Li, Shifeng
Zhang, Pingwen
Shi, An-Chang
Jiang, Kai
Materials Science
Computational Physics
Interparticle interactions with multiple length scales play a pivotal role in the formation and stability of quasicrystals. Choosing a minimal set of length scales to stabilize a given quasicrystal is a challenging problem. To address this challenge, we propose an intelligent screening method (ISM) to design a Landau theory with a minimal number of length scales -- referred to as the minimal Landau theory -- that includes only the essential length scales necessary to stabilize quasicrystals. Based on a generalized multiple-length-scale Landau theory, ISM first evaluates various spectral configurations of candidate structures under a hard constraint. It then identifies the configuration with the lowest free energy. Using this optimal configuration, ISM calculates phase diagrams to explore the thermodynamic stability of desired quasicrystals. ISM can design a minimal Landau theory capable of stabilizing the desired quasicrystals by incrementally increasing the number of length scales. Our application of ISM has not only confirmed known behaviors in 10- and 12-fold quasicrystals but also led to a significant prediction that quasicrystals with 8-, 14-, 16-, and 18-fold symmetry could be stable within three-length-scale Landau models.
title Designing a minimal Landau theory to stabilize desired quasicrystals
topic Materials Science
Computational Physics
url https://arxiv.org/abs/2409.11830