On Self-Propulsion by Oscillations in a Viscous Liquid

Abstract

Suppose that a body B can move by translatory motion with velocity γ in an otherwise quiescent Navier-Stokes liquid, L, filling the entire space outside B. Denote by = (t), t∈R, the one-parameter family of bounded, sufficiently smooth domains of R3, each one representing the configuration of B at time t with respect to a frame with the origin at the center of mass G and axes parallel to those of an inertial frame. We assume that there are no external forces acting on the coupled system S := B + L and that the only driving mechanism is a prescribed change in shape of with time. The self-propulsion problem that we would like to address can be thus qualitatively formulated as follows. Suppose that B changes its shape in a given time-periodic fashion, namely, (t+T) = (t), for some T > 0 and all t ∈ R. Then, find necessary and sufficient conditions on the map t (t) securing that B self-propels, that is, G covers any given finite distance in a finite time. We show that this problem is solvable, in a suitable function class, provided the amplitude of the oscillations is below a given constant. Moreover, we provide examples where the propelling velocity of B is explicitly evaluated in terms of the physical parameters and the frequency of oscillations.

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