Long-Range Order in Coupled D-dimensional Kuramoto Oscillators

Abstract

We show that the long-range order (LRO) strikingly emerges in systems of locally coupled D-dimensional vector Kuramoto oscillators on low-dimensional lattices (d=1,2), but only for odd D. This parity-dependent effect is traced to two-oscillator dynamics, where odd-D units synchronize for any coupling, while even-D pairs require a finite threshold. This fundamental difference selectively seeds collective order in large-scale systems, a phenomenon demonstrated by our numerical simulations. A renormalization group analysis reveals a RG flow to a weak-coupling fixed point for d 2. In this limit, odd-D systems effectively map to a ferromagnetic model, developing an ordered ``hemisphere" phase, whereas even-D systems remain disordered. Our findings further reveal orientational LRO emerges in both d=1 and d=2, but frequency LRO requires d=2. We contrast these results with the established behavior of models possessing continuous symmetry, highlighting how quenched disorder provides a fundamentally new route to order.