Edge insulating topological phases in a two-dimensional superconductor with long-range pairing

Lepori, Luca; Giuliano, Domenico; Paganelli, Simone

doi:10.1103/physrevb.97.041109

Cited by 27 publications

(24 citation statements)

References 62 publications

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“…The analysis of the conditions for the emergence of massive edge states seems to be a promising approach; (ii) the corresponding investigation of the nature of the edge states in LR fermionic systems with dimensionality bigger than one, in order to probe the weakened bulk-boundary correspondence (also following the logic in [80,81]). Interestingly from the experimental and technological points of view, this issue also concerns the possible absence of edge conductivity, present instead for SR topological insulators and superconductors(first examples have been recently given in [87,88]); (iii) the generalization to interacting LR models, also exploiting entanglement indicators (for instance, in the SR limit the ES is proved to be effective also in the presence of explicit interactions [62]); (iv) the study of the effects of stronger deviations from the area-law for the von Neumann entropy, for instance assuming a (almost) volume-law scaling, as in the set of systems investigated in [41]; (v) the understanding of the role of disorder on the singular dynamics in interacting LR systems, as for the LR Ising model. There effects of many-body localization [82] are expected to play a relevant role; (vi) the identification of a general scheme for the experimental detection of the LR phases, for instance based on direct measurements of the entanglement or of some topological invariants, e.g.…”

Section: Discussionmentioning

confidence: 99%

Long-range topological insulators and weakened bulk-boundary correspondence

Lepori

Dell’Anna

2017

New J. Phys.

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We investigate the appearance of new types of insulators and superconductors in long-range (LR) fermionic quantum systems. These phases are not included in the famous 'ten-fold way classification' (TWC), valid in the short-range (SR) limit. This conclusion is obtained analysing at first specific onedimensional models, in particular their phase diagrams and entanglement properties. The LR phases are signalled, for instance, by the violation of the area-law for the von Neumann entropy and by a corresponding peculiar entanglement spectrum (ES). Later on, the origin of the deviations from the TWC is investigated from a more general point of view and in any dimension, showing that it is related with the presence of divergences occurring in the spectrum, due to the LR couplings. A satisfying characterization for the LR phases can be achieved, at least for one-dimensional quantum systems, as well as the definition of a nontrivial topology for them, resulting in the presence of massive edge states, provided a careful evaluation of the LR contributions. Our results allows to infer, at least for onedimensional models, the weakening of the bulk-boundary correspondence, due to the important correlations between bulk and edges, and consequently to clarify the nature of the massive edge states. The emergence of this peculiar edge structure is signalled again by the bulk ES. The stability of the LR phases against local disorder is also discussed, showing notably that this ingredient can even strengthen the effect of the LR couplings. Finally, we analyse the entanglement content of the paradigmatic LR Ising chain, inferring again important deviations from the SR regime, as well as the limitations of bulk-boundary (tensor-network based) approaches to classify LR spin models.

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Section: Discussionmentioning

confidence: 99%

Long-range topological insulators and weakened bulk-boundary correspondence

Lepori

Dell’Anna

2017

New J. Phys.

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“…And there are two different arguments about the reduction of the long-range model to the short-range model. Some works suggest that the reduction happens when α > 1 [25,55,56] and some studies obtain a short-range limit for α > 1.5 [27]. Solving these issues through the study of universality class of critical exponents and CFT can give the better understanding.…”

Section: Outlook and Experimental Possibilitiesmentioning

confidence: 99%

“…On the other hand, long-range topological models are the more generalized version of novel phases of matter [23]. This includes realization of new phases like edge insulating topological phases [24,25] with fractional topological invariants [26] and quasiparticles like Majorana zero modes (MZM), massive majorana modes [27]. In this work, we carry out a theoretical study of a topological longerrange as well as truly long-range model.…”

Section: Introductionmentioning

confidence: 99%

Topological quantum phase transitions and criticality in a longer-range Kitaev chain

et al. 2021

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In an attempt to theoretically investigate the quantum phase transition and criticality in topological models, we study a Kitaev chain with longer-range couplings (finite number of neighbors) as well as truly long-range couplings (infinite number of neighbors). We carry out an extensive topological characterization of the momentum space to explore the possibility of obtaining higher order winding numbers and analyze the nature of their stability in the model. The occurrences of phase transitions from even-to-even and odd-to-odd winding numbers are observed with decreasing longer-rangeness in the system. We derive topological quantum critical lines and study them to understand the behavior of criticality. A suppression of higher order winding numbers is observed with decreasing longer-rangeness in the model. We show that the mechanism behind such phenomena is due to the superposition and vanishing of the topological quantum critical lines associated with the higher winding number. Through the study of the Berry connection, we show the possible different behaviors of critical lines when they undergo superposition along with the corresponding critical exponents. We analyze the behavior of the long-range models through the momentum space characterization. We also provide the exact solution for the problem and discuss the experimental aspects of the work.

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“…The interesting physics associated to LR interaction concerns also fermionic lattice systems, characterized by nontrivial topological invariants [36-38, 69, 72-77]. Notably, for these systems, BE is known to characterize only partially the LR regimes, not being able to distinguish in general the different LR phases [38,74], while ME appears to be more indicative [50][51][52].…”

Section: The Modelmentioning

confidence: 99%

Multipartite-entanglement tomography of a quantum simulator

2019

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Multipartite-entanglement tomography, namely the quantum Fisher information (QFI) calculated with respect to different collective operators, allows to fully characterize the phase diagram of the quantum Ising chain in a transverse field with variable-range interaction. In particular, it recognizes the phase stemming from long-range (LR) antiferromagnetic interaction, a capability also shared by the spin squeezing. Furthermore, the QFI locates the quantum critical points, both with vanishing and nonvanishing mass gap. In this case, we also relate the finite-size power-law exponent of the QFI to the critical exponents of the model, finding a signal for the breakdown of conformal invariance in the deep LR regime. Finally, the effect of a finite temperature on the multipartite entanglement, and ultimately on the phase stability, is considered. In light of the current realizations of the model with trapped ions and of the potential measurability of the QFI, our approach yields a promising strategy to probe LR physics in controllable quantum systems.

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Edge insulating topological phases in a two-dimensional superconductor with long-range pairing

Cited by 27 publications

References 62 publications

Long-range topological insulators and weakened bulk-boundary correspondence

Long-range topological insulators and weakened bulk-boundary correspondence

Topological quantum phase transitions and criticality in a longer-range Kitaev chain

Multipartite-entanglement tomography of a quantum simulator

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