Topological entanglement properties of disconnected partitions in the  Su-Schrieffer-Heeger model

Micallo, Tommaso; Vitale, Vittorio; Dalmonte, Marcello; Fromholz, Pierre

doi:10.21468/scipostphyscore.3.2.012

Cited by 27 publications

(29 citation statements)

References 77 publications

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“…In the following, we assume that the system has been measured in the error basis, yielding a classical string of errors. As the topological phases of the SSH model are SPT phases [22], we need to ensure that the error correction circuit cannot perform operations that violate these symmetries [9]. For example, performing an operation that corrects a single |+ error directly to the |− state would be a violation of the chiral symmetry.…”

mentioning

confidence: 99%

Error-correction properties of an interacting topological insulator

Jamadagni¹,

Weimer²

2021

Preprint

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We analyze the phase diagram of a topological insulator model including antiferromagnetic interactions in the form of an extended Su-Schrieffer Heeger model. To this end, we employ a recently introduced operational definition of topological order based on the ability of a system to perform topological error correction. We show that the necessary error correction statistics can be obtained efficiently using a Monte-Carlo sampling of a matrix product state representation of the ground state wave function. Specifically, we identify two distinct symmetry-protected topological phases corresponding to two different fully dimerized reference states. Finally, we extend the notion of error correction to classify thermodynamic phases to those exhibiting local order parameters, finding a topologically trivial antiferromagnetic phase for sufficiently strong interactions.

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confidence: 99%

Error-correction properties of an interacting topological insulator

Jamadagni¹,

Weimer²

2021

Preprint

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“…Evaluating S D using the free fermion techniques of [44] as outlined in Ref. 43, yields the behavior in Fig. 2(a) for our chain with 2N = 40 sites.…”

Section: Sudden Switching Of a Pumped Non-hermitian Ssh Latticementioning

confidence: 91%

“…To characterize the finite size analog of the bulk topological phase transition we employ here the disconnected entanglement entropy S D introduced in [42,43]. S D is defined in terms of both connected and disconnected entanglement entropies of different segments of the system, in order to cancel out all area and volume law contributions to the bipartite entanglement entropy.…”

Section: Sudden Switching Of a Pumped Non-hermitian Ssh Latticementioning

confidence: 99%

“…For the finite SSH chain in the topological phase, with both periodic and open boundary conditions at large chain length, S D is equal to 2 log 2 as a result of the entanglement of the localized edge states across the full extent of the chain. With open boundary conditions, S D is equal to zero only in the trivial gapped phase, with a smooth transition between the two phases that becomes increasingly abrupt as the chain size increases [43]. Evaluating S D using the free fermion techniques of [44] as outlined in Ref.…”

Section: Sudden Switching Of a Pumped Non-hermitian Ssh Latticementioning

confidence: 99%

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Topological quantum interference in a pumped Su-Schrieffer-Heeger lattice

Li,

Atalaya,

Whaley

2021

Preprint

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We propose a realization of topological quantum interference in a pumped non-Hermitian Su-Schrieffer-Heeger lattice that can be implemented by creation and coherent control of excitonic states of trapped neutral atoms. Our approach is based on realizing sudden delocalization of two localized topological edge states by switching the value of the laser phase controlling the lattice potential to quench the system from the topological to the gapless or trivial non-topological quantum phases of the system. We find interference patterns in the occupation probabilities of excitations on lattice sites, with a transition from a two-excitation interference seen in the absence of pumping to manyexcitation interferences in the presence of pumping. Investigation of the excitation dynamics in both the topological and trivial non-topological phases shows that such interference patterns which originate in topology are drastically distinct from interference between non-topological states of the lattice. Our results also reveal that unlike well-known situations where topological states are protected against local perturbations, in these non-Hermitian SSH systems a local dissipation at each lattice site can suppress both the total population of the lattice in the topological phase and the interference of the topological states.

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“…Apart from the original polymer system, the SSH model was realized experimentally and the topological edge states were detected in more controllable settings such as cold atoms [20][21][22][23], electronic states in artificial atomic lattices [24] or superlattices [25], mechanical chains [26], and photonic systems [27][28][29]. Among theoretically predicted signatures of the topological edge states are effects in the entanglement entropy [30], in the decoherence of a coupled qubit [31], and in transport and noise characteristics in non-equilibrium settings where a current is driven through an SSH chain [32][33][34][35][36]. However, to the best of our knowledge, the archetypal mesoscopic setup of a quantum dot coupled to leads has not yet been studied if the latter are modeled as SSH chains.…”

Section: Introductionmentioning

confidence: 99%

Quantum dot coupled to topological insulators: The role of edge states

Maurer,

Lin,

Kennes

et al. 2021

Preprint

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We investigate a system consisting of one or two topological-insulator leads which are tunnel coupled to a single dot level. The leads are described by the one-dimensional Su-Schrieffer-Heeger model. We show that (topological) edge states cause characteristic features in the dot spectral function, the dot occupation, and the finite-bias current across the dot. As the kinetic energy is quenched in the dot region, local two-particle interactions are of particular relevance there. This motivates us to test whether the aforementioned edge-state features are robust against such interactions; we report here that they are either robust or even enhanced. We conclude that the characteristic features can be used to determine if the leads are in their topologically non-trivial or trivial phase.

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Topological entanglement properties of disconnected partitions in the Su-Schrieffer-Heeger model

Cited by 27 publications

References 77 publications

Error-correction properties of an interacting topological insulator

Error-correction properties of an interacting topological insulator

Topological quantum interference in a pumped Su-Schrieffer-Heeger lattice

Quantum dot coupled to topological insulators: The role of edge states

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