Litcius/Paper detail

Interacting second-order topological insulators in one-dimensional fermions with correlated hopping

A. Montorsi, U. Bhattacharya, Daniel González-Cuadra, Maciej Lewenstein, Giandomenico Palumbo, Luca Barbiero

2022Physical review. B./Physical review. B20 citationsDOI

Abstract

Higher-order topological crystalline phases in low-dimensional interacting quantum systems represent a challenging and largely unexplored research topic. Here, we derive a Hamiltonian describing fermions interacting through correlated hopping processes that break chiral invariance, but preserve both inversion and time-reversal symmetries. In this way, we show that our one-dimensional model gives rise to an interacting second-order topological insulating phase that supports gapped edge states. The topological nature of such an interacting phase turns out to be revealed by both long-range order of a nonlocal string correlation function and by even degeneracy of the entanglement spectrum. For strong interactions we instead find that the topological crystalline phase is destroyed and replaced by a singlet superconducting phase. The latter, characterized by local fermionic pairing, turns out to appear both in a homogeneous and in a phase separated form. Relevantly, the derived one-dimensional model and the second-order topological insulator can be explored and investigated in atomic quantum simulators.

Topics & Concepts

PhysicsTopological orderTopological insulatorTopological degeneracyFermionSymmetry protected topological orderHamiltonian (control theory)Topology (electrical circuits)Homogeneous spacePairingQuantum phasesQuantum entanglementDirac fermionQuantum mechanicsQuantumSuperconductivityQuantum phase transitionMathematical optimizationCombinatoricsGeometryMathematicsTopological Materials and PhenomenaQuantum many-body systemsPhysics of Superconductivity and Magnetism