Generating Entanglement by Quantum Resetting

TL;DR

This paper investigates how stochastic quantum resetting can generate and optimize entanglement in a closed quantum system, providing a framework to analyze nonequilibrium stationary states with quantum correlations.

Contribution

It introduces a general framework for studying correlations in reset quantum systems and applies it to a two-spin model to demonstrate entanglement generation via resetting.

Findings

Quantum resetting creates a nonequilibrium stationary state with quantum entanglement.

Optimal resetting rate and interaction strength maximize entanglement.

Resetting enhances quantum correlations in interacting systems.

Abstract

We consider a closed quantum system subjected to stochastic Poissonian resetting with rate $r$ to its initial state. Resetting drives the system to a nonequilibrium stationary state (NESS) with a mixed density matrix which has both classical and quantum correlations. We provide a general framework to study these NESS correlations for a closed quantum system with a general Hamiltonian $H$. We then apply this framework to a simple model of a pair of ferromagnetically coupled spins, starting from state $\mid\downarrow\downarrow \rangle$ and resetting to the same state with rate $r$. We compute exactly the NESS density matrix of the full system. This then provides access to three basic observables, namely (i) the von Neumann entropy of a subsystem (ii) the fidelity between the NESS and the initial density matrix and (iii) the concurrence in the NESS (that provides a measure of the quantum entanglement in a mixed state), as a function of the two parameters: the resetting rate and the interaction strength. One of our main conclusions is that a nonzero resetting rate and a nonzero interaction strength generates quantum entanglement in the NESS (quantified by a nonzero concurrence) and moreover this concurrence can be maximized by appropriately choosing the two parameters. Our results show that quantum resetting provides a simple and effective mechanism to enhance entanglement between two parts of an interacting quantum system.