A Mixed-Metric Two-Field Framework for Turbulence: Emergent Stress Anisotropy and Wall Asymptotics from a Single Scalar

Abstract

In our previous work~SanchisAgudoVinuesa2025PRL, we argued that viscous dissipation in turbulence can be understood as the macroscopic imprint of microscopic path uncertainty, and showed that a kernel variance field s(y) constrained by a balance condition yields both the Kolmogorov scales and the logarithmic law of the wall from a single stochastic principle. In the present work we promote s to a dynamical field s(x,t) with units of kinematic viscosity and develop a two-field framework in which the velocity and an intermittency (or stochastic diffusivity) field s evolve in a coupled way. The effective viscosity is eff=0+s, but the stress tensor is generalized to include a non-linear closure driven by the commutator of strain and rotation, [S, ], capturing emergent anisotropy. The evolution of s is defined as a mixed-metric gradient flow: a Wasserstein-2 gradient flow for morphology, (s s), combined with a local L2 gradient flow driven by an objective coupling term q. The coupling is decomposed as q=qprod-qrelax, where production is driven by a vortex-stretching invariant, I = \|Sω\|2. This choice ensures that production vanishes identically in strictly two-dimensional flows. We show that, under standard assumptions of constant stress, high Reynolds number and overlap-layer scale invariance, the only scale-invariant overlap-layer solution of the mixed-metric equation is s(y) y, which recovers the logarithmic velocity profile. Thus the same mixed-metric equation organizes both wall-resolved and wall-modeled asymptotics within a single, energetically constrained framework.