Synchronized Aharonov-Bohm Motifs via Engineered Dissipation

TL;DR

This paper demonstrates that engineered dissipation can induce robust, initial-condition-independent spin synchronization in flux-induced localized systems, revealing a link between localization, dissipation, and quantum synchronization.

Contribution

It introduces a method to achieve collective spin synchronization in Aharonov-Bohm motifs using engineered dissipation, regardless of initial states.

Findings

Robust spin synchronization achieved via engineered dissipation.

Synchronization is independent of initial conditions.

Multiple motifs can synchronize through collective dissipation.

Abstract

The interplay between external gauge fields and lattice geometry can induce extreme localization dynamics through complete destructive interference. We show that combining this flux-induced localization with engineered dissipation leads to robust spin synchronization in rotationally symmetric spin geometries, referred to as Aharonov-Bohm motifs, with cyclic symmetries of any order. The synchronized dynamics is independent of initial conditions and features entanglement among spins within each motif. We further demonstrate that multiple motifs can fully synchronize when coupled, which is achieved by applying additional collective dissipation acting on all intra-motif spins. These results reveal a direct connection between flux-induced localization, dissipative engineering, and collective quantum synchronization.