Synchronization and phase transition of two-dimensional self-rotating clock models

Abstract

We explore possible synchronization in two-dimensional (2D) locally coupled discrete-state oscillators under thermal fluctuations, using the self-rotating q-state clock model as a prototype. Large-scale Monte Carlo simulations reveal that for q qc (with qc = 5), the system undergoes two-step Berezinskii-Kosterlitz-Thouless (BKT)-like transitions: first from a disordered phase to a critical synchronized phase, and then to a spatiotemporal pattern phase. Notably, the synchronized phase features algebraically decaying spatial correlations and divergent coherence time, realizing an effective continuous time crystal across macroscopic yet finite scales; while it vanishes when q < qc. A dynamic renormalization group analysis shows this behavior arises from an emergent U(1) symmetry for q qRGc=5, and indicates a crossover scale to Kardar-Parisi-Zhang (KPZ) universality diverges double-exponentially with q, ensuring the pre-asymptotic stability of the synchronized phase. Mean-field theory predicts a lower critical value qcMF = 4.