Related papers: Entanglement growth from squeezing on the MPS manifold

Entanglement growth from squeezing on the MPS manifold

URL: http://arxiv.org/abs/2401.13740v1
Date: Wed, 24 Jan 2024 19:00:04 GMT
Title: Entanglement growth from squeezing on the MPS manifold
Authors: Sebastian Leontica, Andrew G. Green
Abstract summary: We show a previously analytically connection between the Lyapunov spectrum from projection onto the matrix product state (MPS) manifold and the growth of entanglement. Our results rigorously establish the physical significance of the projected Lyapunov spectrum, suggesting it as an alternative method of characterizing chaos in quantum many-body systems.
Score: 0.06526824510982798
License: http://creativecommons.org/licenses/by/4.0/
Abstract: Finding suitable characterizations of quantum chaos is a major challenge in many-body physics, with a central difficulty posed by the linearity of the Schr\"odinger equation. A possible solution for recovering non-linearity is to project the dynamics onto some variational manifold. The classical chaos induced via this procedure may be used as a signature of quantum chaos in the full Hilbert space. Here, we demonstrate analytically a previously heuristic connection between the Lyapunov spectrum from projection onto the matrix product state (MPS) manifold and the growth of entanglement. This growth occurs by squeezing a localized distribution on the variational manifold. The process qualitatively resembles the Cardy-Calabrese picture, where local perturbations to a moving MPS reference are interpreted as bosonic quasi-particles. Taking careful account of the number of distinct channels for these processes recovers the connection to the Lyapunov spectrum. Our results rigorously establish the physical significance of the projected Lyapunov spectrum, suggesting it as an alternative method of characterizing chaos in quantum many-body systems, one that is manifestly linked to classical chaos.

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