Topology-driven quantum phase transitions in time-reversal-invariant anyonic quantum liquids

Gils, Charlotte; Trebst, Simon; Kitaev, Alexei; Ludwig, Andreas; Troyer, Matthias; Wang, Zhenghan

doi:10.1038/nphys1396

Cited by 75 publications

(112 citation statements)

References 43 publications

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“…The first term favors the trivial label 1 on each rung of the ladder, while the second term favors the no-flux state for all plaquettes. As shown in [28], the projector onto the flux through a square plaquette can be expressed in terms of the unitary/non-unitary F-matrices in equations (6) and (7). This term is equivalent to the plaquette term in the Levin-Wen models [51], which are defined on a different lattice, the honeycomb lattice.…”

Section: The Ladder Hamiltonianmentioning

confidence: 99%

“…The analytic solution of the Fibonacci ladder model at the two exactly solvable points has been described in detail in (the supplementary material of) [28]. Thus, we will be rather brief here, and point out some of the crucial steps of the mapping of the ladder model onto an exactly solved (RSOS) model.…”

Section: Analytical Solutionmentioning

confidence: 99%

“…In this way, the model can be mapped on the D 6 version of the RSOS model and, precisely when J r = J p = ±1, the model is critical, and can be solved exactly. We will not go into the details here (which can be found in [28]), but we will quickly state the result for this critical behavior in the original,…”

Section: Analytical Solutionmentioning

confidence: 99%

“…Fibonacci anyons in [28], where we introduce the model in section 3.1. We then discuss the phase diagram in section 3.2, present the analytical solution at special critical points in section 3.3 and finish with exact numerical results in section 3.4.…”

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confidence: 99%

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Microscopic models of interacting Yang–Lee anyons

et al. 2011

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Abstract. Collective states of interacting non-Abelian anyons have recently been studied mostly in the context of certain fractional quantum Hall states, such as the Moore-Read state proposed to describe the physics of the quantum Hall plateau at filling fraction ν = 5/2. In this paper, we further expand this line of research and present non-unitary generalizations of interacting anyon models. In particular, we introduce the notion of Yang-Lee anyons, discuss their relation to the so-called 'Gaffnian' quantum Hall wave function and describe an elementary model for their interactions. A one-dimensional (1D) version of this modela non-unitary generalization of the original golden chain model-can be fully understood in terms of an exact algebraic solution and numerical diagonalization. We discuss the gapless theories of these chain models for general su(2) k anyonic theories and their Galois conjugates. We further introduce and solve a 1D version of the Levin-Wen model for non-unitary Yang-Lee anyons.

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Section: The Ladder Hamiltonianmentioning

confidence: 99%

Section: Analytical Solutionmentioning

confidence: 99%

Section: Analytical Solutionmentioning

confidence: 99%

mentioning

confidence: 99%

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Microscopic models of interacting Yang–Lee anyons

et al. 2011

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“…The Hilbert space maps then directly on the fusion space of Fibonacci anyons and a proper tuning of the laser parameters renders the system into an interacting topological liquid of non-Abelian anyons. We discuss the low-energy properties of this system and show how to experimentally measure anyonic observables.There is great interest in studying many-body systems of interacting anyons as they often exhibit exotic quantum phases [5,[7][8][9]. A further motivation is that the exchange of anyons -the braiding -permits the implementation of robust protocols for quantum information processing [10][11][12].…”

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Interacting Fibonacci anyons in a Rydberg gas

2012

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A defining property of particles is their behavior under exchange. In two dimensions anyons can exist which, opposed to fermions and bosons, gain arbitrary relative phase factors [1] or even undergo a change of their type. In the latter case one speaks of non-Abelian anyons -a particularly simple and aesthetic example of which are Fibonacci anyons [2]. They have been studied in the context of fractional quantum Hall physics where they occur as quasiparticles in the k = 3 Read-Rezayi state [3], which is conjectured to describe a fractional quantum Hall state at filling fraction ν = 12/5 [4]. Here we show that the physics of interacting Fibonacci anyons [5] can be studied with strongly interacting Rydberg atoms in a lattice, when due to the dipole blockade [6] the simultaneous laser excitation of adjacent atoms is forbidden. The Hilbert space maps then directly on the fusion space of Fibonacci anyons and a proper tuning of the laser parameters renders the system into an interacting topological liquid of non-Abelian anyons. We discuss the low-energy properties of this system and show how to experimentally measure anyonic observables.There is great interest in studying many-body systems of interacting anyons as they often exhibit exotic quantum phases [5,[7][8][9]. A further motivation is that the exchange of anyons -the braiding -permits the implementation of robust protocols for quantum information processing [10][11][12]. Physically, anyons emerge as quasi particles on the ground state of an interacting manybody system and recently there has been put much effort in implementing and exploring anyonic models with cold atoms [13][14][15], polar molecules [16] and trapped ions [17]. A model which has been much studied -in particular in the context of quantum information processing -is Kitaev's toric code [18]. Excitations on the ground state are Abelian anyons, which merely acquire a phase when braided. A more complex and exotic scenario is encountered in the non-Abelian case, i.e. when anyons can undergo an actual change of their type under braiding.A particularly simple example of non-Abelian anyons are Fibonacci anyons which occur in two types: A trivial particle referred to as 1 and a non-trivial particle denoted by τ . A convenient way to define an anyonic system is through fusion rules for the particle types (see e.g. Refs.[2, 12]), which for Fibonacci anyons readThe first three rules are a consequence of the trivial nature of a 1-anyon. The fourth rule states that two anyons of type τ can fuse such that the result is either the trivial particle or a τ -anyon. This can be thought of as being analogous to the merging of two spin 1/2 particles ( 1 2 ⊗ 1 2 = 0 ⊕ 1), which can yield either a singlet (total spin 0) or a triplet (total spin 1).For a set of N anyons of type τ it can be shown that a basis of the underlying Hilbert space is spanned by all possible fusion paths [2], i.e. the number of ways in which these anyons can be successively fused. For large N , this number grows as ϕ N with ϕ = (1 + √ 5)/2 being t...

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Chain of interacting SU(2)4 anyons and quantum SU(2) k × $\overline {SU(2)_k } $ doubles

2011

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We consider a chain of SU(2)4 anyons with transitions to a topologically ordered phase state. For half-integer and integer indices of the type of strongly correlated excitations, we find an effective lowenergy Hamiltonian that is an analogue of the standard Heisenberg Hamiltonian for quantum magnets. We describe the properties of the Hilbert spaces of the system eigenstates. For the Drinfeld quantum SU(2) k ×SU(2) k doubles, we use numerical computations to show that the largest eigenvalues of the adjacency matrix for graphs that are extended Dynkin diagrams coincide with the total quantum dimensions for the levels k = 2, 3, 4, 5. We also formulate a hypothesis about the reason for the universal behavior of the system in the long-wave limit.

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Topology-driven quantum phase transitions in time-reversal-invariant anyonic quantum liquids

Cited by 75 publications

References 43 publications

Microscopic models of interacting Yang–Lee anyons

Microscopic models of interacting Yang–Lee anyons

Interacting Fibonacci anyons in a Rydberg gas

Chain of interacting SU(2)4 anyons and quantum SU(2) k × $\overline {SU(2)_k } $ doubles

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