Geometric Mutual Information at Classical Critical Points

Stéphan, Jean-Marie; Inglis, Stephen; Fendley, Paul; Melko, Roger G.

doi:10.1103/physrevlett.112.127204

Cited by 29 publications

(52 citation statements)

References 40 publications

(56 reference statements)

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“…40,41 ), but in slightly different limits. Let us finally mention that universal scaling forms proportional to n/(n − 1) have been found in the 2d classical Rényi mutual information 24 for Ising, as well as in the Rényi entropy of the 2d quantum transverse field Ising model 27 . In both cases the underlying ordering assumption is easier to justify: for the former the critical system is coupled to a bulk in the ordered phase 42 , while for the latter the higher dimensionality makes an extraordinary transition more likely.…”

Section: Path-integral and Replicasmentioning

confidence: 83%

“…Such terms should also impact related quantities in classical systems. For example, the Shannon mutual information of a infinite cylinder (strip) in a 2d classical system is exactly (twice) the Shannon entropy of the dominant eigenvector of the corresponding transfer matrix 24 . Hence by universality the (ln L) 2 contribution should also appear in the 2d MI, most probably also in a finite system.…”

Section: The Peculiar Case Of Open Chainsmentioning

confidence: 99%

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Shannon and Rényi mutual information in quantum critical spin chains

Stéphan

2014

Phys. Rev. B

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We study the Shannon mutual information in one-dimensional critical spin chains, following a recent conjecture (Phys. Rev. Lett. 111, 017201 (2013)[1]), as well as Rényi generalizations of it. We combine conformal field theory arguments with numerical computations in lattice discretizations with central charge c = 1 and c = 1/2. For a periodic system of length L cut into two parts of length ℓ and L − ℓ, all our results agree with the general shape-dependence In(ℓ,, where bn is a universal coefficient. For the free boson CFT we show from general arguments that bn = c = 1. At c = 1/2 we conjecture a result for n > 1. We perform extensive numerical computations in Ising chains to confirm this, and also find b1 ≃ 0.4801629(2), a nontrivial number which we do not understand analytically. Open chains at c = 1/2 and n = 1 are even more intriguing, with a shape-dependent logarithmic divergence of the Shannon mutual information.

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Section: Path-integral and Replicasmentioning

confidence: 83%

Section: The Peculiar Case Of Open Chainsmentioning

confidence: 99%

Shannon and Rényi mutual information in quantum critical spin chains

Stéphan

2014

Phys. Rev. B

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“…Here G n is the so-called geometric mutual information 29 . Interestingly, for critical systems G n depends only on the geometry of A and B, and it is universal.…”

Section: The Booklet Construction and And The Classical Rényi Entropymentioning

confidence: 99%

“…(C2) can be sampled efficiently in Monte Carlo 29 . Notice that the same trick has also been used in Ref.…”

Section: The Replica-symmetric (Rs) Approximationmentioning

confidence: 99%

“…For instance, at a conformally invariant critical point entanglement measures contain universal information about the underlying conformal field theory (CFT), such as the central charge [24][25][26][27] . For classical spin models a lot of attention has been focused on the classical Rényi entropy 28,29 . Given a bipartition of the system into two complementary subregions A and B, the classical Rényi entropy S n (A) (with n ∈ N) is defined as…”

Section: Introductionmentioning

confidence: 99%

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Classical mutual information in mean-field spin glass models

2016

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We investigate the classical Rényi entropy Sn and the associated mutual information In in the SherringtonKirkpatrick (S-K) model, which is the paradigm model of mean-field spin glasses. Using classical Monte Carlo simulations and analytical tools we investigate the S-K model on the n-sheets booklet. This is obtained by gluing together n independent copies of the model, and it is the main ingredient to construct the Rényi entanglementrelated quantities. We find a glassy phase at low temperature, whereas at high temperature the model exhibits paramagnetic behavior, consistent with the regular S-K model. The temperature of the paramagnetic-glassy transition depends non-trivially on the geometry of the booklet. At high-temperatures we provide the exact solution of the model by exploiting the replica symmetry. This is the permutation symmetry among the fictitious replicas that are used to perform disorder averages (via the replica trick). In the glassy phase the replica symmetry has to be broken. Using a generalization of the Parisi solution, we provide analytical results for Sn and In, and for standard thermodynamic quantities. Both Sn and In exhibit a volume law in the whole phase diagram. We characterize the behavior of the corresponding densities Sn/N, In/N , in the thermodynamic limit. Interestingly, at the critical point the mutual information does not exhibit any crossing for different system sizes, in contrast with local spin models.

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Entanglement entropy, dualities, and deconfinement in gauge theories

Anber

Kolligs

2018

J. High Energ. Phys.

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Computing the entanglement entropy in confining gauge theories is often accompanied by puzzles and ambiguities. In this work we show that compactifying the theory on a small circle S 1 L evades these difficulties. In particular, we study Yang-Mills theory on R 3 × S 1 L with double-trace deformations or adjoint fermions and hold it at temperatures near the deconfinement transition. This theory is dual to a multi-component (electric-magnetic) Coulomb gas that can be mapped either to an XY-spin model with Z p symmetry-preserving perturbations or dual Sine-Gordon model. The entanglement entropy of the dual Sine-Gordon model exhibits an extremum at the critical temperature/crossover. We also compute Rényi mutual information (RMI) of the XY-spin model by means of the replica trick and Monte Carlo simulations. These are expensive calculations, since one in general needs to suppress lower winding vortices that do not correspond to physical excitations of the system. We use a T-duality that maps the original XY model to its mirror image, making the extraction of RMI a much efficient process. Our simulations indicate that RMI follows the area law scaling, with subleading corrections, and this quantity can be used as a genuine probe to detect deconfinement transitions. We also discuss the effect of fundamental matter on RMI and the implications of our findings in gauge theories and beyond.

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Geometric Mutual Information at Classical Critical Points

Cited by 29 publications

References 40 publications

Shannon and Rényi mutual information in quantum critical spin chains

Shannon and Rényi mutual information in quantum critical spin chains

Classical mutual information in mean-field spin glass models

Entanglement entropy, dualities, and deconfinement in gauge theories

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