2018
DOI: 10.1103/physrevlett.121.136802
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Non-Hermitian Chern Bands

Abstract: The relation between chiral edge modes and bulk Chern numbers of quantum Hall insulators is a paradigmatic example of bulk-boundary correspondence. We show that the chiral edge modes are not strictly tied to the Chern numbers defined by a non-Hermitian Bloch Hamiltonian. This breakdown of conventional bulk-boundary correspondence stems from the non-Bloch-wave behavior of eigenstates (non-Hermitian skin effect), which generates pronounced deviations of phase diagrams from the Bloch theory. We introduce non-Bloc… Show more

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Cited by 919 publications
(966 citation statements)
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References 96 publications
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“…He − α 1 kx +α 2 ky b , then H is given by H (k,r) = vγ 1kx +vγ 2ky +γ 3 bx+γ 4 bŷ +hσ z −µτ z , (55) which is a special form of Fu-Kane Hamiltonian and has a topological protected zero mode at the defect. Denote the zero mode state of the Fu-Kane Hamiltonian H as Φ 1 (r) = r|Φ 1 , then H has a topological protected zero mode Φ 1 (r) = e iα1∂x/b+iα2∂y/b Φ 1 (r) at the defect.…”
Section: Point Defects In 2d C3 Classmentioning
confidence: 99%
“…He − α 1 kx +α 2 ky b , then H is given by H (k,r) = vγ 1kx +vγ 2ky +γ 3 bx+γ 4 bŷ +hσ z −µτ z , (55) which is a special form of Fu-Kane Hamiltonian and has a topological protected zero mode at the defect. Denote the zero mode state of the Fu-Kane Hamiltonian H as Φ 1 (r) = r|Φ 1 , then H has a topological protected zero mode Φ 1 (r) = e iα1∂x/b+iα2∂y/b Φ 1 (r) at the defect.…”
Section: Point Defects In 2d C3 Classmentioning
confidence: 99%
“…In the future, we anticipate that a levitated optomechanical array will enable many experiments including topological random walk [86][87][88] and other non-Hermitian effects. [89,90] Our work also gives a basic model and inspiration on quantum many-body simulation in the levitated optomechanical array when the system can be further cooled to the quantum regime.…”
Section: Resultsmentioning
confidence: 99%
“…The breakdown of the bulk-boundary correspondence has previously been observed in many different non-Hermitian static systems [22][23][24][25][26][27][28][29]. In these system, the breakdown is a consequence of the non-Hermitian skin effect, in which bulk states are exponentially localized upon the introduction of an open boundary condition, leading to a significant change in the energy spectrum.…”
Section: J δTmentioning
confidence: 99%