2015
DOI: 10.1103/physrevb.92.094204
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Non-Hermitian transparency and one-way transport in low-dimensional lattices by an imaginary gauge field

Abstract: Unidirectional and robust transport is generally observed at the edge of two-or three-dimensional quantum Hall and topological insulator systems. A hallmark of these systems is topological protection, i.e. the existence of propagative edge states that cannot be scattered by imperfections or disorder in the system. A different and less explored form of robust transport arises in non-Hermitian systems in the presence of an imaginary gauge field. As compared to topologically-protected transport in quantum Hall an… Show more

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Cited by 145 publications
(158 citation statements)
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“…Imaginary gauge fields were introduced in a pioneering paper by Hatano and Nelson [6] to study non-Hermitian Anderson localization in disordered lattices, which raised a lively interest [11,12]. Recently, the proposal to implement artificial imaginary gauge fields in integrated photonics using coupled optical microrings with tailored gain and loss regions [13,14] has renewed the interest in the HatanoNelson model, paving the way toward an experimental demonstration of non-Hermitian Anderson delocalization transition. Such previous studies, however, are limited to consider stationary imaginary gauge fields.…”
Section: Discussionmentioning
confidence: 99%
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“…Imaginary gauge fields were introduced in a pioneering paper by Hatano and Nelson [6] to study non-Hermitian Anderson localization in disordered lattices, which raised a lively interest [11,12]. Recently, the proposal to implement artificial imaginary gauge fields in integrated photonics using coupled optical microrings with tailored gain and loss regions [13,14] has renewed the interest in the HatanoNelson model, paving the way toward an experimental demonstration of non-Hermitian Anderson delocalization transition. Such previous studies, however, are limited to consider stationary imaginary gauge fields.…”
Section: Discussionmentioning
confidence: 99%
“…Such a result was subsequently revisited by several authors [11] and connected to the problem of the spectrum of tridiagonal random matrices and random Dirac fermion models [12]. Recently, an optical implementation of the Hatano-Nelson model with an artificial maginary gauge field, based on a chain of coupled optical microrings with tailored gain and loss regions, was suggested [13] and the phenomenon of non-Hermitian transparency was disclosed [14]. In such previous studies [6,[11][12][13][14][15] the imaginary gauge field was considered stationary.…”
Section: Introductionmentioning
confidence: 99%
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“…Regarding line-gapped systems, the topological transition in this case is explained by the winding number of the Q matrix based on the biorthogonal projection operator [132,133,140]. Furthermore, imaginary gauge fields [135,[142][143][144], which indicate paired effective amplification in one way and attenuation to the other, are presented as an intelligible interpretation of these anomalous properties. The skin effect will hence stem from some symmetry breaking induced by non-Hermiticity [135,145].…”
Section: Complex Bandgap and Emergent Non-hermitian Topological Effectsmentioning
confidence: 99%
“…The imaginary gauge field results in nonreciprocal photon tunneling, and leads to asymmetric amplification and attenuation of the counter-propagating waves. Light transport is robust, being insensitive to disorders and imperfections under a non-Hermitian delocalization [11,12]. The light propagation in one direction is shape-preserving and accompanied by persistent amplification.…”
Section: Introductionmentioning
confidence: 99%