Frustrated Fields: Statistical Field Theory for Frustrated Brownian Particles on 2D Manifolds

Abstract

We develop a statistical field theory that describes the large-N limit of a system of Brownian particles with quenched random pairwise interactions on a compact two-dimensional Riemannian manifold. The resulting Frustrated Fields (F2) model is a non-linear field theory for a smooth self-interacting density field on the manifold, with local and non-local (in space and time) self-interactions characteristic of spin-glass dynamics. Particle simulations show adiabatic dimension reduction: on S2, the density concentrates on a slowly precessing great-circle ring whose orientation is a director (n -n, even profile). Conditioned on this simulation-supported ring saddle and on a Born-Oppenheimer separation between the slow orientation and the gapped density fluctuations, symmetry fixes the low-energy dynamics to be the nonlinear sigma model (NLSM) on the real projective plane S2/Z2 = RP2 (the RP2 NLSM on the projective rotor space) in (0+1) dimensions, governed by a single low-energy constant, the rotational diffusion coefficient Drot. With Drot and the static ring profile f0 measured from particle simulations, the resulting effective theory reproduces multiple independent orientation- and density-sector diagnostics with no further adjustable parameters.