Non-Hermitian topological magnonics

IF 23.9 1区 物理与天体物理 Q1 PHYSICS, MULTIDISCIPLINARY Physics Reports Pub Date : 2024-02-09 DOI:10.1016/j.physrep.2024.01.006
Tao Yu , Ji Zou , Bowen Zeng , J.W. Rao , Ke Xia
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Abstract

Dissipation in mechanics, optics, acoustics, and electronic circuits is nowadays recognized to be not always detrimental but can be exploited to achieve non-Hermitian topological phases or properties with functionalities for potential device applications, ranging from sensors with unprecedented sensitivity, energy funneling, wave isolators, non-reciprocal signal amplification, to dissipation induced phase transition. As elementary excitations of ordered magnetic moments that exist in various magnetic materials, magnons are the information carriers in magnonic devices with low-energy consumption for reprogrammable logic, non-reciprocal communication, and non-volatile memory functionalities. Non-Hermitian topological magnonics deals with the engineering of dissipation and/or gain for non-Hermitian topological phases or properties in magnets that are not achievable in the conventional Hermitian scenario, with associated functionalities cross-fertilized with their electronic, acoustic, optic, and mechanic counterparts, such as giant enhancement of magnonic frequency combs, magnon amplification, (quantum) sensing of the magnetic field with unprecedented sensitivity, magnon accumulation, and perfect absorption of microwaves. In this review article, we address the unified approach in constructing magnonic non-Hermitian Hamiltonian, introduce the basic non-Hermitian topological physics, and provide a comprehensive overview of the recent theoretical and experimental progress towards achieving distinct non-Hermitian topological phases or properties in magnonic devices, including exceptional points, exceptional nodal phases, non-Hermitian magnonic SSH model, and non-Hermitian skin effect. We emphasize the non-Hermitian Hamiltonian approach based on the Lindbladian or self-energy of the magnonic subsystem but address the physics beyond it as well, such as the crucial quantum jump effect in the quantum regime and non-Markovian dynamics. We provide a perspective for future opportunities and challenges before concluding this article.

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非赫米拓扑磁学
如今,人们认识到机械、光学、声学和电子电路中的耗散并不总是有害的,而是可以利用耗散来实现非ermitian 拓扑相位或特性,从而实现潜在设备应用的功能,包括具有前所未有灵敏度的传感器、能量漏斗、波隔离器、非互易信号放大,以及耗散诱导的相变。作为存在于各种磁性材料中的有序磁矩的基本激发,磁子是磁子器件中的信息载体,具有低能耗、可重编程逻辑、非互惠通信和非易失性存储器等功能。非赫米拓扑磁学涉及磁体中的非赫米拓扑相或特性的耗散和/或增益工程,这在传统的赫米方案中是无法实现的,相关功能与其电子、声学、光学和机械对应物相互促进,例如磁子频率梳的巨大增强、磁子放大、具有前所未有的灵敏度的磁场(量子)传感、磁子积累和微波的完美吸收。在这篇综述文章中,我们讨论了构建磁子非赫米提哈密顿的统一方法,介绍了基本的非赫米提拓扑物理,并全面概述了在磁子器件中实现独特的非赫米提拓扑相或特性的最新理论和实验进展,包括例外点、例外结点相、非赫米提磁子 SSH 模型和非赫米提趋肤效应。我们强调基于磁子系统的林德布拉第或自能的非全息哈密顿方法,但也涉及其以外的物理学,如量子体系中关键的量子跃迁效应和非马尔可夫动力学。在结束本文之前,我们将展望未来的机遇与挑战。
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来源期刊
Physics Reports
Physics Reports 物理-物理:综合
CiteScore
56.10
自引率
0.70%
发文量
102
审稿时长
9.1 weeks
期刊介绍: Physics Reports keeps the active physicist up-to-date on developments in a wide range of topics by publishing timely reviews which are more extensive than just literature surveys but normally less than a full monograph. Each report deals with one specific subject and is generally published in a separate volume. These reviews are specialist in nature but contain enough introductory material to make the main points intelligible to a non-specialist. The reader will not only be able to distinguish important developments and trends in physics but will also find a sufficient number of references to the original literature.
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