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Auteurs principaux: Ren, Jun-Feng, Li, Jing, Ding, Hai-Tao, Zhang, Dan-Wei
Format: Preprint
Publié: 2024
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Accès en ligne:https://arxiv.org/abs/2404.15628
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author Ren, Jun-Feng
Li, Jing
Ding, Hai-Tao
Zhang, Dan-Wei
author_facet Ren, Jun-Feng
Li, Jing
Ding, Hai-Tao
Zhang, Dan-Wei
contents The geometric properties of quantum states is fully encoded by the quantum geometric tensor. The real and imaginary parts of the quantum geometric tensor are the quantum metric and Berry curvature, which characterize the distance and phase difference between two nearby quantum states in Hilbert space, respectively. For conventional Hermitian quantum systems, the quantum metric corresponds to the fidelity susceptibility and has already been used to specify quantum phase transitions from the geometric perspective. In this work, we extend this wisdom to the non-Hermitian systems for revealing non-Hermitian critical points. To be concrete, by employing numerical exact diagonalization and analytical methods, we calculate the quantum metric and corresponding order parameters in various non-Hermitian models, which include two non-Hermitian generalized Aubry-Andre models and non-Hermitian cluster and mixed-field Ising models. We demonstrate that the quantum metric of eigenstates in these non-Hermitian models exactly identifies the localization transitions, mobility edges, and many-body quantum phase transitions with gap closings, respectively. We further show that this strategy is robust against the finite-size effect and different boundary conditions.
format Preprint
id arxiv_https___arxiv_org_abs_2404_15628
institution arXiv
publishDate 2024
record_format arxiv
spellingShingle Identifying non-Hermitian critical points with quantum metric
Ren, Jun-Feng
Li, Jing
Ding, Hai-Tao
Zhang, Dan-Wei
Quantum Physics
The geometric properties of quantum states is fully encoded by the quantum geometric tensor. The real and imaginary parts of the quantum geometric tensor are the quantum metric and Berry curvature, which characterize the distance and phase difference between two nearby quantum states in Hilbert space, respectively. For conventional Hermitian quantum systems, the quantum metric corresponds to the fidelity susceptibility and has already been used to specify quantum phase transitions from the geometric perspective. In this work, we extend this wisdom to the non-Hermitian systems for revealing non-Hermitian critical points. To be concrete, by employing numerical exact diagonalization and analytical methods, we calculate the quantum metric and corresponding order parameters in various non-Hermitian models, which include two non-Hermitian generalized Aubry-Andre models and non-Hermitian cluster and mixed-field Ising models. We demonstrate that the quantum metric of eigenstates in these non-Hermitian models exactly identifies the localization transitions, mobility edges, and many-body quantum phase transitions with gap closings, respectively. We further show that this strategy is robust against the finite-size effect and different boundary conditions.
title Identifying non-Hermitian critical points with quantum metric
topic Quantum Physics
url https://arxiv.org/abs/2404.15628