Entanglement Dynamics in Monitored Systems and the Role of Quantum Jumps

TL;DR

This paper investigates how quantum jumps influence entanglement dynamics in monitored quantum systems, revealing that jumps can significantly alter entanglement scaling and introducing a new metric to understand these effects.

Contribution

It introduces a novel metric for entanglement gain and loss due to jumps, and develops a stochastic model to explain the impact of quantum jumps on entanglement.

Findings

Quantum jumps can drastically change entanglement dynamics.

A new stochastic model reproduces entanglement behavior.

Weak monitoring leads to a robust logarithmic entanglement phase.

Abstract

Monitored quantum many-body systems display a rich pattern of entanglement dynamics, which is unique to this non-unitary setting. This work studies the effect of quantum jumps on the entanglement dynamics beyond the no-click limit corresponding to a deterministic non-Hermitian evolution. We consider two examples, a monitored SSH model and a quantum Ising chain, for which we show the jumps have remarkably different effects on the entanglement despite having the same statistics as encoded in their waiting-time distribution. To understand this difference, we introduce a new metric, the statistics of entanglement gain and loss due to jumps and non-Hermitian evolution. This insight allows us to build a simple stochastic model of a random walk with partial resetting, which reproduces the entanglement dynamics, and to dissect the mutual role of jumps and non-Hermitian evolution on the entanglement scaling. We demonstrate that significant deviations from the no-click limit arise whenever quantum jumps strongly renormalize the non-Hermitian dynamics, as in the case of the SSH model at weak monitoring or in the Ising chain at large transverse field. On the other hand, we show that the weak monitoring phase of the Ising chain leads to a robust sub-volume logarithmic phase due to weakly renormalized non-Hermitian dynamics.