Self-Similar Decay in the Kraichnan Model of a Passive Scalar

Abstract

We study the two-point correlation function of a freely decaying scalar in Kraichnan's model of advection by a Gaussian random velocity field, stationary and white-noise in time but fractional Brownian in space with roughness exponent 0<ζ<2, appropriate to the inertial-convective range of the scalar. We find all self-similar solutions, by transforming the scaling equation to Kummer's equation. It is shown that only those scaling solutions with scalar energy decay exponent a≤ (d/γ)+1 are statistically realizable, where d is space dimension and γ=2-ζ. An infinite sequence of invariants J, =0,1,2,... is pointed out, where J0 is Corrsin's integral invariant but the higher invariants appear to be new. We show that at least one of the first two invariants, J0 or J1, must be nonzero for realizable initial data. We classify initial data in long-time domains of attraction of the self-similar solutions, based upon these new invariants. Our results support a picture of ``two-scale'' decay with breakdown of self-similarity for a range of exponents (d+γ)/γ< a < (d+2)/γ, analogous to what has recently been found in decay of Burgers turbulence.

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