📝 SummarXiv

Abstract

We formulate a nonsingular loop-space calculus for Yang-Mills (YM) gradient flow directly in terms of Wilson loops. Variations act within the manifold of smooth loops via finite, reparametrization-invariant "dot derivatives," eliminating cusp/backtracking singularities. This yields a closed linear diffusion equation in loop space for Wilson loops. The associated loop operator is gauge invariant and universal; the construction applies to any (Abelian or non-Abelian) gauge group. We then exhibit two classes of exact solutions. (i) A self-dual (Hodge-dual) minimal surface whose exponentiated dual area solves the fixed-point loop equation without contact terms or ambiguities. For planar loops the dual area equals 2*sqrt(2) times the Euclidean minimal area, providing a geometric confinement mechanism. We also show that the ordinary minimal surface in R^4 does not solve the fixed-point equation because the loop operator produces a singular nonzero contribution. (ii) A decaying-flow solution in which the momentum loop performs a periodic random walk on regular star polygons (the "Euler ensemble" known from Navier-Stokes turbulence). Both solutions realize spontaneous quantization: the self-dual one gives a stationary quantized state (a fixed manifold of the flow), while the decaying one yields a quantized trajectory that relaxes to a pure-gauge vacuum along a universal path. Thus we obtain exact solutions for Wilson-loop evolution in YM gradient flow and a concrete route by which quantum-like Wilson-loop statistics emerge from deterministic classical dynamics. We outline implications for confinement in QCD and the role of the above manifolds/trajectories as attractors of the flow.