Perturbed vortex lattices and the stability of nucleated topological phases

Lahtinen, Ville; Ludwig, Andreas; Trebst, Simon

doi:10.1103/physrevb.89.085121

Cited by 43 publications

(41 citation statements)

References 59 publications

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“…Remarkably, (q * , r * ) becomes identical to (q c , r c ) (0.6813, 0.2679) at φ = 0, implying that the ground state is the critical LG state exhibiting macroscopic loops. Furthermore, its lowenergy physics is described by the Ising CFT [27] which is consistent with the expected one [20,[28][29][30]. Therefore, according to these circumstantial evidences, we may conclude that the LG ansatz at φ = 0 is the exact ground state.…”

supporting

confidence: 76%

Abelian and non-Abelian chiral spin liquids in a compact tensor network representation

et al. 2020

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We provide new insights into the Abelian and non-Abelian chiral Kitaev spin liquids on the star lattice using the recently proposed loop gas (LG) and string gas (SG) states [arXiv:1901.05786]. Those are compactly represented in the language of tensor network. By optimizing only one or two variational parameters, accurate ansatze are found in the whole phase diagram of the Kitaev model on the star lattice. In particular, the variational energy of the LG state becomes exact (within machine precision) at two limits in the model, and the criticality at one of those is analytically derived from the LG feature. It reveals that the Abelian CSLs are well demonstrated by the short-ranged LG while the non-Abelian CSLs are adiabatically connected to the critical LG where the macroscopic loops appear. Furthermore, by constructing the minimally entangled states and exploiting their entanglement spectrum and entropy, we identify the nature of anyons and the chiral edge modes in the non-Abelian phase with the Ising conformal field theory.

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supporting

confidence: 76%

Abelian and non-Abelian chiral spin liquids in a compact tensor network representation

et al. 2020

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“…This local gap is defined as in Eqs. (33) and (34), with the specific two-flux state obtained by flipping the (ij ) bond. We note that the selection rules for physical states continue to apply for the moderate disorder considered here.…”

Section: Numerical Results: Disordered Systemmentioning

confidence: 99%

“…(Brief discussions of disorder in the Kitaev model have been given in Refs. [7] and [34], and a Kitaev-style chiral spin-liquid model with random exchange was considered in Ref. [35].)…”

Section: Introductionmentioning

confidence: 99%

Physical states and finite-size effects in Kitaev's honeycomb model: Bond disorder, spin excitations, and NMR line shape

Zschocke

Vojta

2015

Phys. Rev. B

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Kitaev's compass model on the honeycomb lattice realizes a spin liquid whose emergent excitations are dispersive Majorana fermions and static Z 2 gauge fluxes. We discuss the proper selection of physical states for finite-size simulations in the Majorana representation, based on a recent paper by F. L. Pedrocchi, S. Chesi, and D. Loss [Phys. Rev. B 84, 165414 (2011)]. Certain physical observables acquire large finite-size effects, in particular if the ground state is not fermion-free, which we prove to generally apply to the system in the gapless phase and with periodic boundary conditions. To illustrate our findings, we compute the static and dynamic spin susceptibilities for finite-size systems. Specifically, we consider random-bond disorder (which preserves the solubility of the model), calculate the distribution of local flux gaps, and extract the NMR line shape. We also predict a transition to a random-flux state with increasing disorder.

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“…[39], where sufficient randomness of the signs is predicted to drive the system into a gapless thermal metal state. This mechanism has been shown to hold in the context of the honeycomb model [36] and thus it is expected to apply also in the variants of Kitaev spin models. Thus we predict that when L/ l π 2 /4 and ξ/ l 2, i.e., roughly when…”

Section: A Stability Of the Collective States With Odd Chern Numbersmentioning

confidence: 88%

Kitaev spin models from topological nanowire networks

2014

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We show that networks of superconducting topological nanowires can realize the physics of exactly solvable Kitaev spin models on trivalent lattices. This connection arises from the low-energy theory of both systems being described by a tight-binding model of Majorana modes. In Kitaev spin models the Majorana description provides a convenient representation to solve the model, whereas in an array of Josephson junctions of topological nanowires it arises from localized physical Majorana modes tunneling between the wire ends. We explicitly show that an array of junctions of three wires-a setup relevant to topological quantum computing with nanowires-can realize the Yao-Kivelson model, a variant of Kitaev spin models on a decorated honeycomb lattice. Employing properties of the latter, we show that the network can be constructed to give rise to two-dimensional collective topological states characterized by Chern numbers ν = 0, ±1, and ±2, and that defects in the array can be associated with vortex-like quasiparticle excitations. In addition we show that the collective states are stable in the presence of disorder and superconducting phase fluctuations. When the network is operated as a quantum information processor, the connection to Kitaev spin models implies that decoherence mechanisms can in general be understood in terms of proliferation of the vortex-like quasiparticles.

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Perturbed vortex lattices and the stability of nucleated topological phases

Cited by 43 publications

References 59 publications

Abelian and non-Abelian chiral spin liquids in a compact tensor network representation

Abelian and non-Abelian chiral spin liquids in a compact tensor network representation

Physical states and finite-size effects in Kitaev's honeycomb model: Bond disorder, spin excitations, and NMR line shape

Kitaev spin models from topological nanowire networks

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