Scaling of temporal entanglement in proximity to integrability

TL;DR

This paper analytically computes the influence matrix for integrable Floquet models, revealing area-law temporal entanglement and phase diagram insights, which facilitate efficient simulation of quantum dynamics near integrability.

Contribution

It provides the first exact analytical calculation of the influence matrix in integrable Floquet systems, linking temporal entanglement to phase transitions and enabling efficient tensor network simulations.

Findings

IM exhibits area-law temporal entanglement for all parameters.

IM reveals phase transitions through entanglement pattern changes.

Near criticality, temporal entanglement shows non-trivial scaling.

Abstract

Describing dynamics of quantum many-body systems is a formidable challenge due to rapid generation of quantum entanglement between remote degrees of freedom. A promising approach to tackle this challenge, which has been proposed recently, is to characterize the quantum dynamics of a many-body system and its properties as a bath via the Feynman-Vernon influence matrix (IM), which is an operator in the space of time trajectories of local degrees of freedom. Physical understanding of the general scaling of the IM's temporal entanglement and its relation to basic dynamical properties is highly incomplete to present day. In this Article, we analytically compute the exact IM for a family of integrable Floquet models - the transverse-field kicked Ising chain - finding a Bardeen-Cooper-Schrieffer-like "wavefunction" on the Schwinger-Keldysh contour with algebraically decaying correlations. We demonstrate that the IM exhibits area-law temporal entanglement scaling for all parameter values. Furthermore, the entanglement pattern of the IM reveals the system's phase diagram, exhibiting jumps across transitions between distinct Floquet phases. Near criticality, a non-trivial scaling behavior of temporal entanglement is found. The area-law temporal entanglement allows us to efficiently describe the effects of sizeable integrability-breaking perturbations for long evolution times by using matrix product state methods. This work shows that tensor network methods are efficient in describing the effect of non-interacting baths on open quantum systems, and provides a new approach to studying quantum many-body systems with weakly broken integrability.