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 fractional quantum Hall effect in topological flat bands

Zeng, Tian-Sheng

doi:10.1103/physrevb.97.035151

Cited by 20 publications

(14 citation statements)

References 109 publications

(138 reference statements)

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“…Generally speaking, the multicomponent FQH states can be classified by a class of the integer-valued symmetric K matrix of the rank N [8][9][10][11]. The diagnosis of the topological nature of the K matrix has been discussed in our previous works [49,50]. Here we briefly summarize the main strategy.…”

Section: Models and Methodsmentioning

confidence: 99%

Topological characterization of hierarchical fractional quantum Hall effects in topological flat bands with SU( N ) symmetry

Zeng

Zhu

2019

Phys. Rev. B

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We study the many-body ground states of SU(N ) symmetric hardcore bosons on the topological flat-band model by using controlled numerical calculations. By introducing strong intracomponent and intercomponent interactions, we demonstrate that a hierarchy of bosonic SU(N ) fractional quantum Hall (FQH) states emerges at fractional filling factors ν = N/(M N + 1) (odd M = 3). In order to characterize this series of FQH states, we figure the effective K matrix from the inverse of the Chern number matrix. The topological characterization of the K matrix also reveals quantized drag Hall responses and fractional charge pumping that could be detected in future experiments. In addition, we address the general one-to-one correspondence to the spinless FQH states in topological flat bands with Chern number C = N at fillings ν = 1/(M C + 1).

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Section: Models and Methodsmentioning

confidence: 99%

Topological characterization of hierarchical fractional quantum Hall effects in topological flat bands with SU( N ) symmetry

Zeng

Zhu

2019

Phys. Rev. B

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“…For any FQH state, it is a common knowledge that its Hall conductance should be a universal quantized constant σ H = ν regardless of its Abelian/non-Abelian nature, which is related to the topological invariant (so called Chern number) [22]. So far, it has been successful in characterizing Abelian multicomponent quantum Hall states based on the Chern number matrix, namely the inverse of the K = C −1 matrix [23][24][25][26]. Here the diagonal and off-diagonal elements of the Chern number matrix are related to intracomponent and intercomponent Hall transports respectively.…”

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confidence: 99%

Chern number matrix of the non-Abelian spin-singlet fractional quantum Hall effect

Zeng,

Zhu

2021

Preprint

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While the understanding of Abelian topological order is comprehensive, how to describe the internal correlation structure of non-Abelian states is still outstanding. Here, we propose a general scheme based on the many-body Chern number matrix to characterize the non-Abelian multicomponent fractional quantum Hall states at filling factions ν = 2k/(2kM + 3) (k, M ∈ Z). As a concrete example, we study the many-body ground states of two-component bosons in topological flat band models. Utilizing density-matrix renormalization group and exact diagonalization methods, we demonstrate the emergence of the non-Abelian spin-singlet fractional quantum Hall effect under three-body interaction at a total filling factor ν = 4/3 in the lowest Chern band, whose topological nature is classified by six-fold degenerate ground states and fractionally quantized Chern number matrix.

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“…By inserting one flux quantum θ y ↑ = θ, θ y ↓ = 0 from θ = 0 to θ = 2π on the cylinder system, the expectation value of the total particle number N L on the left side equals to N L (θ) = tr[ ρ L (θ) N L ], where ρ L is the reduced density matrix of the corresponding left part. The net charge transfer from the right side to the left side of the system during each cycle is encoded by [46,47]…”

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Continuous phase transition between bosonic integer quantum Hall liquid and a trivial insulator: Evidence for deconfined quantum criticality

Zeng

Zhu

2020

Phys. Rev. B

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The deconfined quantum critical point, a prototype Landau-forbidden transition, could exist in principle in the phase transitions involving symmetry protected topological phase, however, examples of such kinds of transition in physical systems are rare beyond one-dimensional systems. Here, using density-matrix renormlization group calculation, we unveil a bosonic integer quantum Hall phase in two-dimensional correlated honeycomb lattice, by full identification of its internal structure from topological K matrix. Moreover we demonstrate that imbalanced periodic chemical potentials can destroy the bosonic integer quantum Hall state and drive it into a featureless trivial (Mott) insulator, where all physical observables evolve smoothly across the critical point. At the critical point the entanglement entropy reveals a characteristic scaling behavior, which is consistent with the critical field theory as an emergent QED3 with two flavors of Dirac fermions.

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SU(N) fractional quantum Hall effect in topological flat bands

Cited by 20 publications

References 109 publications

Topological characterization of hierarchical fractional quantum Hall effects in topological flat bands with SU( N ) symmetry

Topological characterization of hierarchical fractional quantum Hall effects in topological flat bands with SU( N ) symmetry

Chern number matrix of the non-Abelian spin-singlet fractional quantum Hall effect

Continuous phase transition between bosonic integer quantum Hall liquid and a trivial insulator: Evidence for deconfined quantum criticality

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