Phase Transitions in Turnpike Theory For Mean-Field Games

Abstract

We study a translation-invariant mean-field game on the flat torus with interaction F(x,m)=γ(K*m)(x), where K is smooth, even, and mean-zero. The interaction is of potential type, arising as the first variation of a quadratic energy, though the stationary system is not treated variationally. Linearizing around the uniform equilibrium yields mode-wise 2× 2 systems with dispersion σξ(γ)=ν2(2π|ξ|)4+γ(2π|ξ|)2 K(ξ). If K is negative for some mode, a finite threshold \[ γc= K(ξ)<0ν2(2π|ξ|)2| K(ξ)| \] marks loss of stability; otherwise γc=+∞. Near criticality, the spectral gap scales as ρ(γ) C*γc-γ. For γ<γc, the uniform state is exponentially stable in the turnpike sense for finite-horizon problems, with rate ρ(γ). At γ=γc, the gap closes and, after phase fixing and center-manifold reduction, one obtains algebraic midpoint decay of order T-1/2. For γ>γc, a branch of nonuniform stationary solutions bifurcates via a pitchfork-type amplitude equation, with translations generating the full family. Finally, under standard asymptotic-consistency assumptions on symmetric N-player equilibria in the subcritical regime, we obtain qualitative propagation of chaos, without quantitative rates.