Phase transitions and linear stability for the mean-field Kuramoto-Daido model

Abstract

We consider the mean-field noisy Kuramoto-Daido model, which is a McKean-Vlasov equation on the circle with bimodal interaction W(θ)=θ+m2θ for m 0 and interaction strength K, generalizing the celebrated noisy Kuramoto model corresponding to m=0. Our first contribution is to characterize the phase transition threshold Kc by comparing it to the linear stability threshold K\# = (1, m-1) of the uniform distribution. When m ≤ 1/2, Kc=1, coinciding with that of the Kuramoto model. On the other hand, for m ≥ 2, we show Kc= m-1. We also classify the regimes in which the phase transition is continuous or discontinuous. Our second contribution is to analyze the linear stability of a global minimizer q (the ``ordered phase'') of the mean-field free energy in the supercritical regime K>1. This stationary solution of the Kuramoto-Daido equation is unique up to translation invariance and distinct from the uniform distribution (the ``disordered phase''). Our approach extends the Dirichlet form method of Bertini et al. from the unimodal to bimodal setting. In particular, for m ≤ 1.590 × 10-4 and K>1, we show an explicit lower bound on the spectral gap of the linearized McKean-Vlasov operator at q. To our knowledge, this is the first rigorous stability analysis for this class of models with bimodal interactions.