Diffusion of passive scalar in a finite-scale random flow
Abstract
We consider a solvable model of the decay of scalar variance in a single-scale random velocity field. We show that if there is a separation between the flow scale kflow-1 and the box size kbox-1, the decay rate lambda ~ (kbox/kflow)2 is determined by the turbulent diffusion of the box-scale mode. Exponential decay at the rate lambda is preceded by a transient powerlike decay (the total scalar variance ~ t-5/2 if the Corrsin invariant is zero, t-3/2 otherwise) that lasts a time t~1/λ. Spectra are sharply peaked at k=kbox. The box-scale peak acts as a slowly decaying source to a secondary peak at the flow scale. The variance spectrum at scales intermediate between the two peaks (kbox<<k<<kflow) is ~ k + a k2 + ... (a>0). The mixing of the flow-scale modes by the random flow produces, for the case of large Peclet number, a k-1+delta spectrum at k>>kflow, where delta ~ lambda is a small correction. Our solution thus elucidates the spectral make up of the ``strange mode,'' combining small-scale structure and a decay law set by the largest scales.
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