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Main Authors: Wang, Shu-Xuan, Yan, Zhongbo
Format: Preprint
Published: 2025
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Online Access:https://arxiv.org/abs/2501.12875
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author Wang, Shu-Xuan
Yan, Zhongbo
author_facet Wang, Shu-Xuan
Yan, Zhongbo
contents The emergence of exceptional points in non-Hermitian systems represents an intriguing phenomenon characterized by the coalescence of eigenenergies and eigenstates. When a system approaches an exceptional point, it exhibits a heightened sensitivity to perturbations compared to the conventional band degeneracy observed in Hermitian systems. This sensitivity, manifested in the splitting of the eigenenergies, is amplified as the order of the exceptional point increases. Infernal points constitute a unique subclass of exceptional points, distinguished by their order escalating with the expansion of the system's size. In this paper, we show that, when a non-Hermitian system is at an infernal point, a perturbation of strength $ε$, which couples the two opposing boundaries of the system, causes the eigenenergies to split according to the law $\sqrt[k]ε$, where $k$ is an integer proportional to the system's size. Utilizing the perturbation theory of Jordan matrices, we demonstrate that the exceptional sensitivity of the eigenenergies at infernal points to boundary-coupling perturbations is a ubiquitous phenomenon, irrespective of the specific form of the non-Hermitian Hamiltonians. Notably, we find that this phenomenon remains robust even when the system deviates substantially from the infernal point. The universal nature and robustness of this phenomenon suggest potential applications in enhancing sensor sensitivity.
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spellingShingle Super-enhanced Sensitivity in Non-Hermitian Systems at Infernal Points
Wang, Shu-Xuan
Yan, Zhongbo
Mesoscale and Nanoscale Physics
The emergence of exceptional points in non-Hermitian systems represents an intriguing phenomenon characterized by the coalescence of eigenenergies and eigenstates. When a system approaches an exceptional point, it exhibits a heightened sensitivity to perturbations compared to the conventional band degeneracy observed in Hermitian systems. This sensitivity, manifested in the splitting of the eigenenergies, is amplified as the order of the exceptional point increases. Infernal points constitute a unique subclass of exceptional points, distinguished by their order escalating with the expansion of the system's size. In this paper, we show that, when a non-Hermitian system is at an infernal point, a perturbation of strength $ε$, which couples the two opposing boundaries of the system, causes the eigenenergies to split according to the law $\sqrt[k]ε$, where $k$ is an integer proportional to the system's size. Utilizing the perturbation theory of Jordan matrices, we demonstrate that the exceptional sensitivity of the eigenenergies at infernal points to boundary-coupling perturbations is a ubiquitous phenomenon, irrespective of the specific form of the non-Hermitian Hamiltonians. Notably, we find that this phenomenon remains robust even when the system deviates substantially from the infernal point. The universal nature and robustness of this phenomenon suggest potential applications in enhancing sensor sensitivity.
title Super-enhanced Sensitivity in Non-Hermitian Systems at Infernal Points
topic Mesoscale and Nanoscale Physics
url https://arxiv.org/abs/2501.12875