Corroborating the bulk-edge correspondence in weakly interacting one-dimensional topological insulators

Zegarra, Antonio; Candido, Denis R.; Egues, J. Carlos; Chen, Wei

doi:10.1103/physrevb.100.075114

Cited by 7 publications

(5 citation statements)

References 54 publications

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“…Consequently, the Fourier transform of the curvature function represents the amplitude of the convoluted Green's function propagating over a certain distance [28]. Moreover, the gap closure at the TPTs can be identified from the spectral function, and the zero energy topological edge state can be pinpointed from the local density of states, corroborating the bulk-edge correspondence in the presence of interactions [64].…”

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confidence: 65%

Unifying topological phase transitions in non-interacting, interacting, and periodically driven systems

Molignini

Читра

Chen

2020

EPL

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Topological phase transitions occur in real materials as well as quantum engineered systems, all of which differ greatly in terms of dimensionality, symmetries, interactions, and driving, and hence require a variety of techniques and concepts to describe their topological properties. For instance, topology may be accessed from single-particle Bloch wave functions, Green's functions, or many-body wave functions. We demonstrate that despite this diversity, all topological phase transitions display a universal feature: namely, a divergence of the curvature function that composes the topological invariant at the critical point. This feature can be exploited via a renormalization-group-like methodology to describe topological phase transitions. This approach serves to extend notions of correlation function, critical exponents, scaling laws and universality classes used in Landau theory to characterize topological phase transitions in a unified manner.

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confidence: 65%

Unifying topological phase transitions in non-interacting, interacting, and periodically driven systems

Molignini

Читра

Chen

2020

EPL

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“…where c I i is the spinless fermion annihilation operator on sublattice I = {A, B} at site i, t + δt and t − δt are the hopping amplitudes on the even and the odd bonds, respectively, and Q k = (t + δt) + (t − δt)e −ik after a Fourier transform. We consider the nearest-neighbor interaction [14,35]…”

Section: Su-schrieffer-heeger Model With Nearest-neighbor Interactionmentioning

confidence: 99%

A supervised learning algorithm for interacting topological insulators based on local curvature

Molignini

Zegarra

Nieuwenburg³

et al. 2021

SciPost Phys.

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Topological order in solid state systems is often calculated from the integration of an appropriate curvature function over the entire Brillouin zone. At topological phase transitions where the single particle spectral gap closes, the curvature function diverges and changes sign at certain high symmetry points in the Brillouin zone. These generic properties suggest the introduction of a supervised machine learning scheme that uses only the curvature function at the high symmetry points as input data. { We apply this scheme to a variety of interacting topological insulators in different dimensions and symmetry classes. We demonstrate that an artificial neural network trained with the noninteracting data can accurately predict all topological phases in the interacting cases with very little numerical effort.} Intriguingly, the method uncovers a ubiquitous interaction-induced topological quantum multicriticality in the examples studied.

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“…In addition, effects of ac and dc fields [45][46][47], long range perturbations [48], effects of next neighbours [49,50] and thermoelectric properties [51] were studied well. Furthermore, edge states transport blockade [52], results of multi-edge states [53], effects of many-body interactions in addition to bulk-edge correspondence and the quantum criticality in weakly interacting systems by using the Green's function for calculating the many-body curvature function [54,55], out-of-equilibrium bulk-boundary correspondence [56], Zeeman fields and spin orbit coupling [57][58][59] and topological properties of domain wall states [60] were deliberated.…”

Section: Introductionmentioning

confidence: 99%

Topological spintronics in a polyacetylene molecule device

Keshtan

Esmaeilzadeh

2020

J. Phys.: Condens. Matter

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Using the Su-Schrieffer-Heeger Hamiltonian and exploiting the Green's function method in the framework of the Landauer-Büttiker formalism, the topological and spin dependent electron transport properties of a trans polyacetylene molecule are studied. It is found that molecules with the intracell single carbon-carbon bonding and the even number of monomers in their chains have two edge states and possess topological properties though their Hamiltonians do not respect the chiral symmetry. A perpendicular exchange magnetic field and two perpendicular and transverse electric fields are used to induce and manipulate the quantum spin dependent electron transport properties. The exchange field induces the spin polarization in different electron energy regions which are expanded by stronger exchange fields. Therefore this proposed device works as a perfect spin filter. The spin polarization can be manipulated by applying the perpendicular electric field and remains robust against the transverse electric field variations.

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Corroborating the bulk-edge correspondence in weakly interacting one-dimensional topological insulators

Cited by 7 publications

References 54 publications

Unifying topological phase transitions in non-interacting, interacting, and periodically driven systems

Unifying topological phase transitions in non-interacting, interacting, and periodically driven systems

A supervised learning algorithm for interacting topological insulators based on local curvature

Topological spintronics in a polyacetylene molecule device

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