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Geometric contribution to adiabatic amplification in non-Hermitian systems

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Geometric contribution to adiabatic amplification in non-Hermitian systems. / Ozawa, Tomoki; Schomerus, Henning.
In: arXiv, Vol. 2024, 2409.13595v1, 20.09.2024.

Research output: Contribution to Journal/MagazineJournal article

Harvard

Ozawa, T & Schomerus, H 2024, 'Geometric contribution to adiabatic amplification in non-Hermitian systems', arXiv, vol. 2024, 2409.13595v1. <https://arxiv.org/abs/2409.13595v1>

APA

Ozawa, T., & Schomerus, H. (2024). Geometric contribution to adiabatic amplification in non-Hermitian systems. arXiv, 2024, Article 2409.13595v1. https://arxiv.org/abs/2409.13595v1

Vancouver

Ozawa T, Schomerus H. Geometric contribution to adiabatic amplification in non-Hermitian systems. arXiv. 2024 Sept 20;2024:2409.13595v1.

Author

Ozawa, Tomoki ; Schomerus, Henning. / Geometric contribution to adiabatic amplification in non-Hermitian systems. In: arXiv. 2024 ; Vol. 2024.

Bibtex

@article{90ad2aaab5594d089658643a361d6686,
title = "Geometric contribution to adiabatic amplification in non-Hermitian systems",
abstract = "Concepts from non-Hermitian quantum mechanics have proven useful in understanding and manipulating a variety of classical systems, such as encountered in optics, classical mechanics, and metamaterial design. Recently, the non-Hermitian analog of the Berry phase for adiabatic processes has been experimentally measured. In non-Hermitian systems, the Berry phase can have an imaginary part, which contributes to the amplification or decay of the total wave intensity. When the imaginary part of the Berry curvature is zero, this geometric amplification factor is determined solely by the initial and final points of the adiabatic path in parameter space, and does not depend on how these points are connected by the path. We list classes of non-Hermitian Hamiltonians where this path independence is guaranteed by suitable symmetries, and find that, for some of these classes, the amplification factor can be written only in terms of the Petermann factors of the initial and final points. Our result can, in turn, be used to experimentally obtain the Petermann factor by observing how the norm of the wavefunction changes under adiabatic processes. We validate our theory using a couple of concrete examples of physical relevance.",
author = "Tomoki Ozawa and Henning Schomerus",
year = "2024",
month = sep,
day = "20",
language = "English",
volume = "2024",
journal = "arXiv",
issn = "2331-8422",

}

RIS

TY - JOUR

T1 - Geometric contribution to adiabatic amplification in non-Hermitian systems

AU - Ozawa, Tomoki

AU - Schomerus, Henning

PY - 2024/9/20

Y1 - 2024/9/20

N2 - Concepts from non-Hermitian quantum mechanics have proven useful in understanding and manipulating a variety of classical systems, such as encountered in optics, classical mechanics, and metamaterial design. Recently, the non-Hermitian analog of the Berry phase for adiabatic processes has been experimentally measured. In non-Hermitian systems, the Berry phase can have an imaginary part, which contributes to the amplification or decay of the total wave intensity. When the imaginary part of the Berry curvature is zero, this geometric amplification factor is determined solely by the initial and final points of the adiabatic path in parameter space, and does not depend on how these points are connected by the path. We list classes of non-Hermitian Hamiltonians where this path independence is guaranteed by suitable symmetries, and find that, for some of these classes, the amplification factor can be written only in terms of the Petermann factors of the initial and final points. Our result can, in turn, be used to experimentally obtain the Petermann factor by observing how the norm of the wavefunction changes under adiabatic processes. We validate our theory using a couple of concrete examples of physical relevance.

AB - Concepts from non-Hermitian quantum mechanics have proven useful in understanding and manipulating a variety of classical systems, such as encountered in optics, classical mechanics, and metamaterial design. Recently, the non-Hermitian analog of the Berry phase for adiabatic processes has been experimentally measured. In non-Hermitian systems, the Berry phase can have an imaginary part, which contributes to the amplification or decay of the total wave intensity. When the imaginary part of the Berry curvature is zero, this geometric amplification factor is determined solely by the initial and final points of the adiabatic path in parameter space, and does not depend on how these points are connected by the path. We list classes of non-Hermitian Hamiltonians where this path independence is guaranteed by suitable symmetries, and find that, for some of these classes, the amplification factor can be written only in terms of the Petermann factors of the initial and final points. Our result can, in turn, be used to experimentally obtain the Petermann factor by observing how the norm of the wavefunction changes under adiabatic processes. We validate our theory using a couple of concrete examples of physical relevance.

M3 - Journal article

VL - 2024

JO - arXiv

JF - arXiv

SN - 2331-8422

M1 - 2409.13595v1

ER -