Gespeichert in:
Bibliographische Detailangaben
Hauptverfasser: Azizi, Pegah, Kundu, Rahul Dev, Li, Weichen, Sun, Kai, Zhang, Xiaojia Shelly, Gonella, Stefano
Format: Preprint
Veröffentlicht: 2025
Schlagworte:
Online-Zugang:https://arxiv.org/abs/2503.17320
Tags: Tag hinzufügen
Keine Tags, Fügen Sie den ersten Tag hinzu!
_version_ 1866909547542609920
author Azizi, Pegah
Kundu, Rahul Dev
Li, Weichen
Sun, Kai
Zhang, Xiaojia Shelly
Gonella, Stefano
author_facet Azizi, Pegah
Kundu, Rahul Dev
Li, Weichen
Sun, Kai
Zhang, Xiaojia Shelly
Gonella, Stefano
contents Topological states of matter, first discovered in quantum systems, have opened new avenues for wave manipulation beyond the quantum realm. In elastic media, realizing these topological effects requires identifying lattices that support the corresponding topological bands. However, among the vast number of theoretically predicted topological states, only a small fraction has been physically realized. To close this gap, we present a new strategy capable of systematically and efficiently discovering metamaterials with any desired topological state. Our approach builds on topological quantum chemistry (TQC), which systematically classifies topological states by analyzing symmetry properties at selected wavevectors. Because this method condenses the topological character into mathematical information at a small set of wavevectors, it encodes a clear and computationally efficient objective for topology optimization algorithms. We demonstrate that, for certain lattice symmetries, this classification can be further reduced to intuitive morphological features of the phonon band structure. By incorporating these band morphology constraints into topology optimization algorithms and further fabricating obtained designs, we enable the automated discovery and physical realization of metamaterials with targeted topological properties. This methodology establishes a new paradigm for engineering topological elastic lattices on demand, addressing the bottleneck in material realization and paving the way for a comprehensive database of topological metamaterial configurations.
format Preprint
id arxiv_https___arxiv_org_abs_2503_17320
institution arXiv
publishDate 2025
record_format arxiv
spellingShingle Lattice Materials with Topological States Optimized On-Demand
Azizi, Pegah
Kundu, Rahul Dev
Li, Weichen
Sun, Kai
Zhang, Xiaojia Shelly
Gonella, Stefano
Materials Science
Topological states of matter, first discovered in quantum systems, have opened new avenues for wave manipulation beyond the quantum realm. In elastic media, realizing these topological effects requires identifying lattices that support the corresponding topological bands. However, among the vast number of theoretically predicted topological states, only a small fraction has been physically realized. To close this gap, we present a new strategy capable of systematically and efficiently discovering metamaterials with any desired topological state. Our approach builds on topological quantum chemistry (TQC), which systematically classifies topological states by analyzing symmetry properties at selected wavevectors. Because this method condenses the topological character into mathematical information at a small set of wavevectors, it encodes a clear and computationally efficient objective for topology optimization algorithms. We demonstrate that, for certain lattice symmetries, this classification can be further reduced to intuitive morphological features of the phonon band structure. By incorporating these band morphology constraints into topology optimization algorithms and further fabricating obtained designs, we enable the automated discovery and physical realization of metamaterials with targeted topological properties. This methodology establishes a new paradigm for engineering topological elastic lattices on demand, addressing the bottleneck in material realization and paving the way for a comprehensive database of topological metamaterial configurations.
title Lattice Materials with Topological States Optimized On-Demand
topic Materials Science
url https://arxiv.org/abs/2503.17320