Design and characterization of all two-dimensional fragile topological bands
Designing topological materials with specific topological indices is a complex inverse problem, traditionally tackled through manual, intuition-driven methods that are neither scalable nor efficient for exploring the vast space of possible material configurations. In this work, we develop an algorit...
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| creator | Bird, Samuel Devescovi, Chiara Engeler, Pascal Valenti, Agnes Gökmen, Doruk Efe Worreby, Robin Peri, Valerio Huber, Sebastian D |
| description | Designing topological materials with specific topological indices is a
complex inverse problem, traditionally tackled through manual, intuition-driven
methods that are neither scalable nor efficient for exploring the vast space of
possible material configurations. In this work, we develop an algorithm that
leverages the covariance matrix adaptation evolution strategy to optimize the
Fourier representation of the periodic functions shaping the designer
material's characteristics. This includes mass profiles or dielectric tensors
for phononic and photonic crystals, respectively, as much as synthetic
potentials applicable to electronic and ultra-cold atomic systems. We
demonstrate our methodology with a detailed characterization of a class of
topological bands known as "fragile topological", showcasing the algorithm's
capability to address both topological characteristics and spectral quality.
This automation not only streamlines the design process but also significantly
expands the potential for identifying and constructing high quality designer
topological materials across the wide range of platforms, and is readily
extendable to other setups, including higher-dimensional and non-linear
systems. |
| doi_str_mv | 10.48550/arxiv.2410.10484 |
| format | Article |
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complex inverse problem, traditionally tackled through manual, intuition-driven
methods that are neither scalable nor efficient for exploring the vast space of
possible material configurations. In this work, we develop an algorithm that
leverages the covariance matrix adaptation evolution strategy to optimize the
Fourier representation of the periodic functions shaping the designer
material's characteristics. This includes mass profiles or dielectric tensors
for phononic and photonic crystals, respectively, as much as synthetic
potentials applicable to electronic and ultra-cold atomic systems. We
demonstrate our methodology with a detailed characterization of a class of
topological bands known as "fragile topological", showcasing the algorithm's
capability to address both topological characteristics and spectral quality.
This automation not only streamlines the design process but also significantly
expands the potential for identifying and constructing high quality designer
topological materials across the wide range of platforms, and is readily
extendable to other setups, including higher-dimensional and non-linear
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complex inverse problem, traditionally tackled through manual, intuition-driven
methods that are neither scalable nor efficient for exploring the vast space of
possible material configurations. In this work, we develop an algorithm that
leverages the covariance matrix adaptation evolution strategy to optimize the
Fourier representation of the periodic functions shaping the designer
material's characteristics. This includes mass profiles or dielectric tensors
for phononic and photonic crystals, respectively, as much as synthetic
potentials applicable to electronic and ultra-cold atomic systems. We
demonstrate our methodology with a detailed characterization of a class of
topological bands known as "fragile topological", showcasing the algorithm's
capability to address both topological characteristics and spectral quality.
This automation not only streamlines the design process but also significantly
expands the potential for identifying and constructing high quality designer
topological materials across the wide range of platforms, and is readily
extendable to other setups, including higher-dimensional and non-linear
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complex inverse problem, traditionally tackled through manual, intuition-driven
methods that are neither scalable nor efficient for exploring the vast space of
possible material configurations. In this work, we develop an algorithm that
leverages the covariance matrix adaptation evolution strategy to optimize the
Fourier representation of the periodic functions shaping the designer
material's characteristics. This includes mass profiles or dielectric tensors
for phononic and photonic crystals, respectively, as much as synthetic
potentials applicable to electronic and ultra-cold atomic systems. We
demonstrate our methodology with a detailed characterization of a class of
topological bands known as "fragile topological", showcasing the algorithm's
capability to address both topological characteristics and spectral quality.
This automation not only streamlines the design process but also significantly
expands the potential for identifying and constructing high quality designer
topological materials across the wide range of platforms, and is readily
extendable to other setups, including higher-dimensional and non-linear
systems.</abstract><doi>10.48550/arxiv.2410.10484</doi><oa>free_for_read</oa></addata></record> |
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| subjects | Physics - Materials Science Physics - Mesoscale and Nanoscale Physics |
| title | Design and characterization of all two-dimensional fragile topological bands |
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