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Main Authors: Wang, Chen-Yang, Xu, Jing-Ping, Wang, Ce, Yang, Ya-Ping
Format: Preprint
Published: 2025
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Online Access:https://arxiv.org/abs/2512.24822
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author Wang, Chen-Yang
Xu, Jing-Ping
Wang, Ce
Yang, Ya-Ping
author_facet Wang, Chen-Yang
Xu, Jing-Ping
Wang, Ce
Yang, Ya-Ping
contents Floquet engineering offers an unparalleled platform for realizing novel non-equilibrium topological phases. However, the unique structure of Floquet systems, which includes multiple quasienergy gaps, poses a significant challenge to classification using conventional analytical methods. We propose a novel unsupervised machine learning framework that employs a kernel defined in momentum-time ($\boldsymbol{k},t$) space, constructed directly from Floquet-Bloch eigenstates. This approach is intrinsically data-driven and requires no prior knowledge of the underlying topological invariants, providing a fundamental advantage over prior methods that rely on abstract concepts like the micromotion operator or homotopic transformations. Crucially, this work successfully reveals the intrinsic topological characteristics encoded within the Floquet eigenstates themselves. We demonstrate that our method robustly and simultaneously identifies the topological invariants associated with both the $0$-gap and the $π$-gap across various symmetry classes (1D AIII, 1D D, and 2D A), establishing a robust methodology for the systematic classification and discovery of complex non-equilibrium topological matter.
format Preprint
id arxiv_https___arxiv_org_abs_2512_24822
institution arXiv
publishDate 2025
record_format arxiv
spellingShingle Unsupervised Topological Phase Discovery in Periodically Driven Systems via Floquet-Bloch State
Wang, Chen-Yang
Xu, Jing-Ping
Wang, Ce
Yang, Ya-Ping
Quantum Physics
Quantum Gases
Floquet engineering offers an unparalleled platform for realizing novel non-equilibrium topological phases. However, the unique structure of Floquet systems, which includes multiple quasienergy gaps, poses a significant challenge to classification using conventional analytical methods. We propose a novel unsupervised machine learning framework that employs a kernel defined in momentum-time ($\boldsymbol{k},t$) space, constructed directly from Floquet-Bloch eigenstates. This approach is intrinsically data-driven and requires no prior knowledge of the underlying topological invariants, providing a fundamental advantage over prior methods that rely on abstract concepts like the micromotion operator or homotopic transformations. Crucially, this work successfully reveals the intrinsic topological characteristics encoded within the Floquet eigenstates themselves. We demonstrate that our method robustly and simultaneously identifies the topological invariants associated with both the $0$-gap and the $π$-gap across various symmetry classes (1D AIII, 1D D, and 2D A), establishing a robust methodology for the systematic classification and discovery of complex non-equilibrium topological matter.
title Unsupervised Topological Phase Discovery in Periodically Driven Systems via Floquet-Bloch State
topic Quantum Physics
Quantum Gases
url https://arxiv.org/abs/2512.24822