Related papers: A statistical approach to topological entanglement: Boltzmann machine representation of high-order irreducible correlation

A statistical approach to topological entanglement: Boltzmann machine representation of high-order irreducible correlation

URL: http://arxiv.org/abs/2302.03212v3
Date: Tue, 7 Nov 2023 17:56:49 GMT
Title: A statistical approach to topological entanglement: Boltzmann machine representation of high-order irreducible correlation
Authors: Shi Feng, Deqian Kong and Nandini Trivedi
Abstract summary: A quantum analog of high-order correlations is the topological entanglement in topologically ordered states of matter at zero temperature. In this work, we propose a statistical interpretation that unifies the two under the same information-theoretic framework.
Score: 6.430262211852815
License: http://creativecommons.org/licenses/by/4.0/
Abstract: Strongly interacting systems can be described in terms of correlation functions at various orders. A quantum analog of high-order correlations is the topological entanglement in topologically ordered states of matter at zero temperature, usually quantified by topological entanglement entropy (TEE). In this work, we propose a statistical interpretation that unifies the two under the same information-theoretic framework. We demonstrate that the existence of a non-zero TEE can be understood in the statistical view as the emergent $n$th order mutual information $I_n$ (for arbitrary integer $n\ge 3$) reflected in projectively measured samples, which also makes explicit the equivalence between the two existing methods for its extraction -- the Kitaev-Preskill and the Levin-Wen construction. To exploit the statistical nature of $I_n$, we construct a restricted Boltzmann machine (RBM) which captures the high-order correlations and correspondingly the topological entanglement that are encoded in the distribution of projected samples by representing the entanglement Hamiltonian of a local region under the proper basis. Furthermore, we derive a closed form which presents a method to interrogate the trained RBM, making explicit the analytical form of arbitrary order of correlations relevant for $I_n$. We remark that the interrogation method for extracting high-order correlation can also be applied to the construction of auxiliary fields that disentangle many-body interactions relevant for diverse interacting models.

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