Topological flat band models with arbitrary Chern numbers

Yang, Shuming; Gu, Zheng Cheng; Sun, Kai; Sarma, S. Das

doi:10.1103/physrevb.86.241112

Cited by 185 publications

(196 citation statements)

References 47 publications

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“…Although close to experimental limits, the resulting Casimir pressure at such a separation is still within observable bounds [36]. Alternatively, multiorbital [29] or multilayer materials [25,28] with possible larger gaps can bring the force even further within measurable values.…”

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confidence: 99%

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Repulsive Casimir Effect with Chern Insulators

Rodriguez-López

Grushin

2014

Phys. Rev. Lett.

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We theoretically predict that the Casimir force in vacuum between two Chern insulator plates can be repulsive (attractive) at long distances whenever the sign of the Chern numbers characterizing the two plates are opposite (equal). A unique feature of this system is that the sign of the force can be tuned simply by turning over one of the plates or alternatively by electrostatic doping. We calculate and take into account the full optical response of the plates and argue that such repulsion is a general phenomena for these systems as it relies on the quantized zero frequency Hall conductivity. We show that achieving repulsion is possible with thin films of Cr-doped ðBi; SbÞ 2 Te 3 , that were recently discovered to be Chern insulators with quantized Hall conductivity. DOI: 10.1103/PhysRevLett.112.056804 PACS numbers: 73.23.-b, 03.70.+k, 41.20.-q, 72.20.-i More than half a century after its theoretical prediction, the Casimir effect [1] still stands among the most intriguing quantum phenomena. The relatively recent quantitative experimental access to the physics of this effect [2], the force experienced by objects due to quantum vacuum fluctuations, has revealed that it is still far from being completely understood. Despite the development of useful calculating tools in terms of the scattering formalism [3,4], the possibility of achieving repulsion in vacuum between two material plates is still so far unreachable experimentally. Two dielectrics can repel when immersed in a medium with very specific optical properties [5,6] and no mirror-symmetric situation can give rise to repulsion [7,8]. These restrictions turn the search for repulsion in vacuum into a difficult challenge that can potentially solve stiction issues [2,9]. Earlier proposals include magnetic materials [10], metamaterials [11,12], engineered geometries [13], and quantum Hall effect (QHE) systems [14], where the latter was subsequently generalized to a QHE system made out of doped graphene sheets [15]. In [16,17], the concept of a topological Casimir effect was explored using three-dimensional topological insulators (TI) [18,19], which owing to their topological electromagnetic (EM) response, opened the way to a tunable repulsion. In these works, the finite frequency part of the topological response [20] arising from the EM response encoded in the θ term [21,22] was assumed to be the quantized zero frequency response for all frequencies, which is only valid for certain distance scales depending on material parameters.In this Letter, we propose to achieve and manipulate repulsion by exploring the Casimir force arising due to the topological nature of Chern insulators (CI). These general class of two dimensional materials have a quantized Hall conductivity in the absence of external magnetic field due to the nontrivial topological structure of the Bloch bands [18,19,23]. The Chern number C ∈ Z is the topological attribute of each band that, if finite, indicates a quantized contribution to the Hall conductivity at zero frequency σ xy ð0Þ ¼ Ce 2 =h. ...

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confidence: 99%

“…Our results point towards TI thin films and other systems with higher Chern numbers [25][26][27][28][29] as the most promising future route to realize and control Casimir repulsion.…”

mentioning

confidence: 99%

Repulsive Casimir Effect with Chern Insulators

Rodriguez-López

Grushin

2014

Phys. Rev. Lett.

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“…To realize topological state with higher Chern number, one can resort to complicated hoppings [28] or lattices [29]. Nonetheless, the simple triangular lattice favors some topologically nontrivial states, it can produce topological state with higher Chern number by merely the nearest-neighbor hoppings [30,31].…”

Section: Introductionmentioning

confidence: 99%

Topological Fulde-Ferrell superfluids in triangular lattices

Guo

2017

Phys. Rev. A

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Fulde-Ferrell (FF) Larkin-Ovchinnikov (LO) phases were proposed for superconductors or superfluids in strong magnetic field. With the experimental progresses in ultracold atomic systems, topological FFLO phases has also been put forward, since it is a natural consequence of realizable spin-orbital coupling (SOC). In this work, we theoretically investigate a triangular lattice model with SOC and in-plane field. By constructing the phase diagram, we show that it can produce topological FF states with Chern numbers, C = ±1 and C = −2. We get the phase boundaries by the change of the sign of Pfaffian. The chiral edge states for different topological FF phases are also elucidated.

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“…1 into one equivalent single-layer square lattice with Chern number two, as engineered in Ref. 10 . Similarly, we stack the other two-component CB lattices H σ CB , σ = 3, 4 in Eq.…”

Section: B Su(n ) Fqh States With N >mentioning

confidence: 99%

“…In analogy to the Laughlin fractional quantum Hall (FQH) states in two-dimensional Landau levels 7 , recent numerical studies suggest that a rich series of Abelian FCI emerges when single-component particles partially occupy topological flat bands with higher Chern number C > 1 at fillings ν = 1/(M C + 1) (M = 1 for hardcore bosons and for M = 2 spinless fermions) [8][9][10][11][12][13][14] . For C = 2, these FCIs are believed to be color-entangled lattice versions of two-component Halperin (mmn) FQH states 15 , and the corresponding Haldane pseudopotential Hamiltonians for these FCIs can be constructed [16][17][18] .…”

Section: Introductionmentioning

confidence: 99%

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

Zeng

2018

Phys. Rev. B

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We study N -component interacting particles (hardcore bosons and fermions) loaded in topological lattice models with SU(N )-invariant interactions based on exact diagonalization and density matrix renormalization group method. By tuning the interplay of interspecies and intraspecies interactions, we demonstrate that a class of SU(N ) fractional quantum Hall states can emerge at fractional filling factors ν = N/(N + 1) for bosons (ν = N/(2N + 1) for fermions) in the lowest Chern band, characterized by the nontrivial fractional Hall responses and the fractional charge pumping. Moreover, we establish a topological characterization based on the K matrix, and discuss the close relationship to the fractional quantum Hall physics in topological flat bands with Chern number N .

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Topological flat band models with arbitrary Chern numbers

Cited by 185 publications

References 47 publications

Repulsive Casimir Effect with Chern Insulators

Repulsive Casimir Effect with Chern Insulators

Topological Fulde-Ferrell superfluids in triangular lattices

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

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