An exact solution to dispersion of a passive scalar by a periodic shear flow

Abstract

We present an exact analytical solution to the problem of shear dispersion given a general initial condition. The solution is expressed as an infinite series expansion involving Mathieu functions and their eigenvalues. The eigenvalue system depends on the imaginary parameter q=2ikPe, with k the wavenumber that determines the tracer scale in the initial condition and Pe the P\'eclet number. Solutions are valid for all Pe, t>0, and k>0 except at specific values of q=qEP called Exceptional Points (EPs), the first occurring at q0EP≈1.468i. For values of q 1.468i, all the eigenvalues are real, different and eigenfunctions decay with time, thus shear dispersion can be represented as a diffusive process. For values of q 1.468i, pairs of eigenvalues coalesce at EPs becoming complex conjugates, the eigenfunctions propagate and decay with time, and so shear dispersion is no longer a purely diffusive process. The limit q→0 is approached by the small P\'eclet number limit for all finite k>0, or equally by the large P\'eclet number limit as long as 2k 1/Pe. The latter implies k→0, strong separation of scales between the tracer and flow. The limit q→∞ results from large P\'eclet number for any k>0, or from large k and non-vanishing Pe. We derive an exact closure that is continuous in wavenumber space. At small q, the closure approaches a diffusion operator with an effective diffusivity proportional to U02/, for flow speed U0 and diffusivity . At large q, the closure approaches the sum of an advection operator plus a half-derivative operator (differential operator of fractional order), the latter with coefficient proportional to U0.

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