Short-time behavior of advecting-diffusing scalar fields in Stokes flows

This article addresses the short-term decay of advecting-diffusing scalar fields in Stokes flows. The analysis is developed in two main subparts. In the first part, we present an analytic approach for a class of simple flow systems expressed mathematically by the one-dimensional advection-diffusion equation w(y)partial derivative(xi)phi = epsilon partial derivative(2)(y)phi + i V (y)phi - epsilon'phi, where xi is either time or axial coordinate and i V (y) an imaginary potential. This class of systems encompasses both open- and closed-flow models and corresponds to the dynamics of a single Fourier mode in parallel flows. We derive an analytic expression for the short-time (short-length) decay of phi, and show that this decay is characterized by a universal behavior that depends solely on the singularity of the ratio of the transverse-to-axial velocity components V-eff(y) = V(y)/w(y), corresponding to the effective potential in the imaginary potential formulation. If V-eff(y) is smooth, then parallel to phi parallel to(L2)(xi) = exp(-epsilon'xi - b xi(3)), where b > 0 is a constant. Conversely, if the effective potential is singular, then parallel to phi parallel to(L2)(xi) = 1 - a xi(v) with a > 0. The exponent. attains the value 5/3 at the very early stages of the process, while for intermediate stages its value is 3/5. By summing over all of the Fourier modes, a stretched exponential decay is obtained in the presence of nonimpulsive initial conditions, while impulsive conditions give rise to an early-stage power-law behavior. In the second part, we consider generic, chaotic, and nonchaotic autonomous Stokes flows, providing a kinematic interpretation of the results found in the first part. The kinematic approach grounded on the warped-time transformation complements the analytical theory developed in the first part.