Clebsch Confinement and Instantons in Turbulence

Abstract

We introduce a concept of Clebsch confinement related to unbroken gauge invariance and study Clebsch instantons: singular vorticity sheets with nontrivial helicity. This is realization of the "Instantons and intermittency" program we started back in the 90tiesFKLM. These singular solutions are involved in enhancing infinitesimal random forces at remote boundary leading to critical phenomena. In the Euler equation vorticity is concentrated along the random self-avoiding surface, with tangent components proportional to the delta function of normal distance. Viscosity in Navier-Stokes equation smears this delta function to the Gaussian with width h 35 at 0 with fixed energy flow. These instantons dominate the enstrophy in dissipation as well as the PDF for velocity circulation C around fixed loop C in space. At large loops, the resulting symmetric exponential distribution perfectly fits the numerical simulationsIBS20 including pre-exponential factor 1/||. At small loops, we advocate relation of resulting random self-avoiding surface theory with multi-fractal scaling laws observed in numerical simulations. These laws are explained as a result of fluctuating internal metric (Liouville field). The curve of anomalous dimensions ζ(n) can be fitted at small n to the parabola, coming from the Liouville theory with two parameters α, Q. At large n the ratios of the subsequent moments in our theory grow linearly with the size of the loop, which corresponds to finite value of ζ(∞) in agreement with DNS.