Non-Hermitian bulk–boundary correspondence in quantum dynamics

Liu, Xiao; Deng, Tian-Shu; Wang, Kunkun; Zhu, Gaoyan; Wang, Zhong; Wu, Yi; Xue, Peng

doi:10.1038/s41567-020-0836-6

Cited by 686 publications

(392 citation statements)

References 46 publications

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“…Broader implications of NHSE have been under investigations [25,32,33,37,58,[88][89][90][91][92][93][94][95][96][97][98][99]. Very recently, NHSE has been observed in experiments [100][101][102].…”

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confidence: 99%

Non-Hermitian Skin Effect and Chiral Damping in Open Quantum Systems

2019

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One of the unique features of non-Hermitian Hamiltonians is the non-Hermitian skin effect, namely that the eigenstates are exponentially localized at the boundary of the system. For open quantum systems, a short-time evolution can often be well described by the effective non-Hermitian Hamiltonians, while long-time dynamics calls for the Lindblad master equations, in which the Liouvillian superoperators generate time evolution. In this Letter, we find that Liouvillian superoperators can exhibit the non-Hermitian skin effect, and uncover its unexpected physical consequences. It is shown that the non-Hermitian skin effect dramatically shapes the long-time dynamics, such that the damping in a class of open quantum systems is algebraic under periodic boundary condition but exponential under open boundary condition. Moreover, the non-Hermitian skin effect and non-Bloch bands cause a chiral damping with a sharp wavefront. These phenomena are beyond the effective non-Hermitian Hamiltonians; instead, they belong to the non-Hermitian physics of full-fledged open quantum dynamics.Model.-The system is illustrated in Fig.1(a). Our Hamiltonian H = ij h ij c † i c j , where c † i , c i are fermion creation and annihilation operators at site i (including

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confidence: 99%

Non-Hermitian Skin Effect and Chiral Damping in Open Quantum Systems

2019

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“…A particular point of interest is the observation of the non-Hermitian skin effect [65][66][67][68][69][70][71], whereby all Eigen states of one-dimensional (1D) systems are localized at a boundary, in sharp contrast with the extend Bloch modes of Hermitian counterparts. This intriguing feature of non-Hermitian lattices has recently been experimentally demonstrated using topo electrical circuits [72] and quantum walks of single photons [73]. Further theoretical investigations have also shown higher order skin modes localized at corners and edges of 2D and 3D non-Hermitian lattices [74,75].…”

Section: Introductionmentioning

confidence: 86%

Dynamics and topology of non-Hermitian elastic lattices with non-local feedback control interactions

Rosa

Ruzzene

2020

New J. Phys.

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We investigate non-Hermitian elastic lattices characterized by non-local feedback interactions. In one-dimensional lattices, proportional feedback produces non-reciprocity associated with complex dispersion relations characterized by gain and loss in opposite propagation directions. For non-local controls, such non-reciprocity occurs over multiple frequency bands characterized by opposite non-reciprocal behavior. The dispersion topology is investigated with focus on winding numbers and non-Hermitian skin effect, which manifests itself through bulk modes localized at the boundaries of finite lattices. In two-dimensional lattices, non-reciprocity is associated with directional wave amplification. Moreover, the combination of skin effect in two directions produces modes that are localized at the corners of finite two-dimensional lattices. Our results describe fundamental properties of non-Hermitian elastic lattices, and suggest new possibilities for the design of meta materials with novel functionalities related to selective wave filtering, amplification and localization. The considered non-local lattices also provide a platform for the investigation of topological phases of non-Hermitian systems.

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“…The non-Hermitian skin effect presents a conceptual obstacle for building a bulk-boundary correspondence as typically the topological invariants are based on the bulk eigenstates of the system, which in these cases may have a completely different character than the eigenstates of the finite system, no matter how large [47]. We note that, after submission of this article, different experiments have put forward realizations of this anomalous localization in topoelectrical circuits [106,107], quantum walks [108] mechanical systems [109] and magnons [110].…”

Section: Extreme Defectiveness From Higher-order Exceptional Points Amentioning

confidence: 99%

Perspective on topological states of non-Hermitian lattices

Torres

2019

J. Phys. Mater.

134

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The search of topological states in non-Hermitian systems has gained a strong momentum over the last two years climbing to the level of an emergent research front. In this perspective we give an overview with a focus on connecting this topic to others like Floquet systems. Furthermore, using a simple scattering picture we discuss an interpretation of concepts like the Hamiltonian's defectiveness, i.e. the lack of a full basis of eigenstates, crucial in many discussions of topological phases of non-Hermitian Hamiltonians.

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Non-Hermitian bulk–boundary correspondence in quantum dynamics

Cited by 686 publications

References 46 publications

Non-Hermitian Skin Effect and Chiral Damping in Open Quantum Systems

Non-Hermitian Skin Effect and Chiral Damping in Open Quantum Systems

Dynamics and topology of non-Hermitian elastic lattices with non-local feedback control interactions

Perspective on topological states of non-Hermitian lattices

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