Noise-induced synchronization in coupled quantum oscillators

TL;DR

This paper investigates how correlated environmental noise can induce long-lasting synchronization and quantum entanglement between coupled quantum oscillators, with analytical solutions revealing the role of symmetry and correlations.

Contribution

It provides an analytical framework showing that environmental correlations can lead to persistent synchronization and entanglement in quantum oscillators, highlighting the role of Lindblad dissipator symmetry.

Findings

Synchronization persists for long times near resonance.

Environmental noise correlation induces quantum entanglement.

Symmetry of the Lindblad dissipator influences relaxation dynamics.

Abstract

We consider the quantum dynamics of a pair of coupled quantum oscillators coupled to a common correlated dissipative environment. The resulting equations of motion for both the operator moments and covariances can be integrated analytically using the Lyapunov equations. We find that for fully correlated and fully anti-correlated environments, the oscillators relax into a phase-synchronized state that persists for long times when the two oscillators are nearly resonant and (essentially) forever if the two oscillators are in resonance. This can be traced to the symmetry of the Lindblad dissipator, which can lead to strong damping in one region of state space and under damping in others. In the extreme cases of fully correlated or fully anti-correlated environments, specific regions of state space are fully decoupled from the environment. We also show that the environmental noise correlation leads to quantum entanglement, and all the correlations between the two oscillators are purely quantum mechanical in origin. This work provides a robust mathematical foundation for understanding how long-lived exciton coherences can be linked to vibronic correlation effects.