Entanglement entropy in the Lipkin-Meshkov-Glick model

Latorre, José I.; Orús, Román; Rico, E.; Vidal, Julien

doi:10.1103/physreva.71.064101

Cited by 244 publications

(346 citation statements)

References 32 publications

(47 reference statements)

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“…In D spatial dimensions, most ground states of local Hamiltonians obey a boundary law (often also referred to as "area law") for entanglement entropy [63][64][65][66][67][68][69][70] , in the sense that the entanglement entropy of a hyperblock A of L D sites scales as the size |∂A| of its boundary ∂A,…”

Section: B Entanglement Entropymentioning

confidence: 99%

Tensor Network States and Geometry

2011

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Tensor network states are used to approximate ground states of local Hamiltonians on a lattice in D spatial dimensions. Different types of tensor network states can be seen to generate different geometries. Matrix product states (MPS) in D = 1 dimensions, as well as projected entangled pair states (PEPS) in D > 1 dimensions, reproduce the D-dimensional physical geometry of the lattice model; in contrast, the multi-scale entanglement renormalization ansatz (MERA) generates a (D+1)-dimensional holographic geometry. Here we focus on homogeneous tensor networks, where all the tensors in the network are copies of the same tensor, and argue that certain structural properties of the resulting many-body states are preconditioned by the geometry of the tensor network and are therefore largely independent of the choice of variational parameters. Indeed, the asymptotic decay of correlations in homogeneous MPS and MERA for D = 1 systems is seen to be determined by the structure of geodesics in the physical and holographic geometries, respectively; whereas the asymptotic scaling of entanglement entropy is seen to always obey a simple boundary lawthat is, again in the relevant geometry. This geometrical interpretation offers a simple and unifying framework to understand the structural properties of, and helps clarify the relation between, different tensor network states. In addition, it has recently motivated the branching MERA, a generalization of the MERA capable of reproducing violations of the entropic boundary law in D > 1 dimensions.

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Section: B Entanglement Entropymentioning

confidence: 99%

Tensor Network States and Geometry

2011

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“…16) Since 2000, there have been a lot of work demonstrating the application of entanglement as an auxilary signature of QPT. [17][18][19][20][21] Moreover, the energy of the ground state and the low excited states are also very important in understanding the QPT. Generally, these quantities are not easy to be calculated for the quantum FK model because the number of classcially excited equilibrium configurations is very huge and the band gap is exponentially small as the system size is increased.…”

Section: Introductionmentioning

confidence: 99%

A Density-Matrix Renormalization Group Study of a One-Dimensional Incommensurate Quantum Frenkel–Kontorova Model

Wang

et al. 2014

J. Phys. Soc. Jpn.

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In this paper, the one-dimensional incommensurate quantum Frenkel-Kontorova model is investigate by a density-matrix renormalization group algorithm. Special attention is given to the entanglement and the ground state energy. The energy gap between the ground state and the first excited is also calculated. From all the numerical results, we have observed an obvious property changes from the pinned state to the sliding one as the quantum fluctuation is increased. But no expected quantum critical point can be justified by the present data.

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“…Firstly, in the vicinity of the two critical points at φ = 0 and φ = 0.9 the logarithm of the zeros density follows the second order scaling fit of (28). We tabulate our fitting results to (28) with recent DMRG and exact diagonalization studies [45][47] [49]. Furthermore, the system size at which our analysis appears to be come unreliable directly corresponds to the range of volumes that can be treated in these recent studies, which indicates a potential common dominant source of systematic error in the numerical roundoff errors from diagonalization.…”

Section: B Critical Scaling Exponentsmentioning

confidence: 99%

“…This nonanalytic term and correction to the area law FSS of the entanglement entropy of quantum spin chains has been also identified in Density Matrix Renormalization Group and Exact Diagonalization calculations in [45][46] [47].…”

Section: Entanglement Entropymentioning

confidence: 99%

The partition function zeroes of quantum critical points

Crompton¹

2009

Nuclear Physics B

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The Lee-Yang theorem for the zeroes of the partition function is not strictly applicable to quantum systems because the zeroes are defined in units of the fugacity e h∆τ , and the Euclidean-time lattice spacing ∆τ can be divergent in the infrared (IR). We recently presented analytic arguments describing how a new space-Euclidean time zeroes expansion can be defined, which reproduces Lee and Yang's scaling but avoids the unresolved branch points associated with the breaking of nonlocal symmetries such as parity. We now present a first numerical analysis for this new zeros approach for a quantum spin chain system. We use our scheme to quantify the renormalization group flow of the physical lattice couplings to the IR fixed point of this system. We argue that the generic Finite-Size Scaling (FSS) function of our scheme is identically the entanglement entropy of the lattice partition function and, therefore, that we are able to directly extract the central charge, c, of the quantum spin chain system using conformal predictions for the scaling of the entanglement entropy.

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Entanglement entropy in the Lipkin-Meshkov-Glick model

Cited by 244 publications

References 32 publications

Tensor Network States and Geometry

Tensor Network States and Geometry

A Density-Matrix Renormalization Group Study of a One-Dimensional Incommensurate Quantum Frenkel–Kontorova Model

The partition function zeroes of quantum critical points

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