Quantum fidelity for degenerate ground states in quantum phase transitions

Yao, Shujie; Hu, Burong; Li, Sheng-Hao; Cho, Sam Young

doi:10.1103/physreve.88.032110

Cited by 19 publications

(17 citation statements)

References 45 publications

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“…Since its early development this approach has been applied successfully to a wide variety of systems, ranging from quasi-free Fermions [198,199], the Dicke model [158,161,193,200], matrix product state systems [201], Bose-Hubbard models [202,203], Stoner-Hubbard and BCS models [51]. Various methods have been developed to evaluate the fidelity, such as exact diagonalisation, density matrix renormalisation group [160,204,205], quantum Monte Carlo methods [195,206,207], tensor network algorithms [208,209]. This provides the means to venture into the study of models where analytical solutions are not available [160,204,205,207,210,211].…”

Section: Introductionmentioning

confidence: 99%

Geometry of quantum phase transitions

2020

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In this article we provide a review of geometrical methods employed in the analysis of quantum phase transitions and non-equilibrium dissipative phase transitions. After a pedagogical introduction to geometric phases and geometric information in the characterisation of quantum phase transitions, we describe recent developments of geometrical approaches based on mixed-state generalisation of the Berry-phase, i.e. the Uhlmann geometric phase, for the investigation of non-equilibrium steady-state quantum phase transitions (NESS-QPTs). Equilibrium phase transitions fall invariably into two markedly non-overlapping categories: classical phase transitions and quantum phase transitions, whereas in NESS-QPTs this distinction may fade off. The approach described in this review, among other things, can quantitatively assess the quantum character of such critical phenomena. This framework is applied to a paradigmatic class of lattice Fermion systems with local reservoirs, characterised by Gaussian non-equilibrium steady states. The relations between the behaviour of the geometric phase curvature, the divergence of the correlation length, the character of the criticality and the gap-either Hamiltonian or dissipative-are reviewed.

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Section: Introductionmentioning

confidence: 99%

Geometry of quantum phase transitions

2020

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“…As discussed [23], spontaneous symmetry breaking leads to a degenerate groundstate for the broken-symmetry phase. Consequently, the relations between the local order parameters calculated from degenerate groundstates are determined by a symmetry group of the system Hamiltonian.…”

Section: Order Parametersmentioning

confidence: 99%

“…For one-dimensional spin lattice systems, doubly degenerate ground states for broken-symmetry phases have been detected by means of the quantum fidelity bifurcations with the tensor network algorithm in various spin lattice models such as the quantum Ising model, spin-1/2 XYX model with transverse magnetic field, among others [20][21][22]. Very recently, Su et al [23] have further demonstrated that the quantum fidelity measured by an arbitrary reference state can detect and identify explicitly all degenerate ground states (N-fold degenerate groundstates) due to spontaneous symmetry breaking in broken-symmetry phases for the infinite matrix product state (iMPS) representation in the one-dimensional (1D) q-state quantum Potts model. It has been also discussed how each order parameter calculated from degenerate ground states transforms under a subgroup of a symmetry group of the Hamiltonian.…”

Section: Introductionmentioning

confidence: 99%

“…The infinite time-evolving block decimation (iTEBD) method [5] will be used to calculate iPEPS groundstate wavefunctions with randomly chosen 2D initial states. In order to distinguish degenerate groundstate wavefunctions of broken-symmetry phases and to determine phase transition points, the quantum fidelity [23], defined as an overlap measurement between an arbitrary 2D reference state and the iPEPS groundstates of the system, will be employed. The defined quantum fidelity corresponds to a projection of each 2D iPEPS groundstate onto a chosen 2D reference state.…”

Section: Introductionmentioning

confidence: 99%

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Degenerate ground states and multiple bifurcations in a two-dimensionalq-state quantum Potts model

et al. 2014

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We numerically investigate the two-dimensional q-state quantum Potts model on the infinite square lattice by using the infinite projected entangled-pair state (iPEPS) algorithm. We show that the quantum fidelity, defined as an overlap measurement between an arbitrary reference state and the iPEPS groundstate of the system, can detect q-fold degenerate groundstates for the Z q broken-symmetry phase. Accordingly, a multiple-bifurcation of the quantum groundstate fidelity is shown to occur as the transverse magnetic field varies from the symmetry phase to the broken-symmetry phase, which means that a multiple-bifurcation point corresponds to a critical point. A (dis-)continuous behavior of quantum fidelity at phase transition points characterizes a (dis-)continuous phase transition. Similar to the characteristic behavior of the quantum fidelity, the magnetizations, as order parameters, obtained from the degenerate groundstates exhibit multiple bifurcation at critical points. Each order parameter is also explicitly demonstrated to transform under the subgroup of the Z q symmetry group. We find that the q-state quantum Potts model on the square lattice undergoes a discontinuous (first-order) phase transition for q = 3 and q = 4, and a continuous phase transition for q = 2 (the 2D quantum transverse Ising model).

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“…For q = 2, 3 and 4 there is a continuous phase transitions at λ = 1, whilst for q = 5 the phase transition is first-order (discontinuous) at λ = 1. Here we remark that the fidelity per site has been demonstrated to be capable of detecting the discontinuous phase transitions in this model through the so-called multiple bifurcation points 31 .…”

Section: Resultsmentioning

confidence: 76%

Universal Order Parameters and Quantum Phase Transitions: A Finite-Size Approach

Shi

Zhou

Batchelor

2015

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We propose a method to construct universal order parameters for quantum phase transitions in many-body lattice systems. The method exploits the H-orthogonality of a few near-degenerate lowest states of the Hamiltonian describing a given finite-size system, which makes it possible to perform finite-size scaling and take full advantage of currently available numerical algorithms. An explicit connection is established between the fidelity per site between two H-orthogonal states and the energy gap between the ground state and low-lying excited states in the finite-size system. The physical information encoded in this gap arising from finite-size fluctuations clarifies the origin of the universal order parameter. We demonstrate the procedure for the one-dimensional quantum formulation of the q-state Potts model, for q = 2, 3, 4 and 5, as prototypical examples, using finite-size data obtained from the density matrix renormalization group algorithm.

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Quantum fidelity for degenerate ground states in quantum phase transitions

Cited by 19 publications

References 45 publications

Geometry of quantum phase transitions

Geometry of quantum phase transitions

Degenerate ground states and multiple bifurcations in a two-dimensionalq-state quantum Potts model

Universal Order Parameters and Quantum Phase Transitions: A Finite-Size Approach

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