Article ID Journal Published Year Pages File Type
9727993 Physica A: Statistical Mechanics and its Applications 2005 33 Pages PDF
Abstract
The theory leading to the general expressions for the flow fields under the above-mentioned limitations exploit the inverse transformation, and the reflection and translation properties of the axisymmetric biharmonic function associated with the Stokes flow. These are cast in the form of a theorem followed by a simple proof. The theorem is then applied to construct closed form singularity solutions for several axisymmetric flow fields disturbed by a hybrid droplet. The different primary flow fields considered here include paraboloidal flow, flow due to a, single stokeslet and a pair of stokelets, and flow due to a potential-dipole. The salient features of the image singularities are discussed in each case. In all cases, the drag force is found to vary significantly with respect to the two radii associated with the two-sphere geometry of the droplet, and the viscosity ratio of the two liquids in the continuous and dispersed phases. In the case of singularity driven flows, the drag is influenced by an additional parameter namely, the location of the singularity. The flow streamlines in some cases show interesting flow patterns. In the case of paraboloidal flows, either a single eddy or a pair of eddies is observed depending on the ratio of the two radii. The sizes and shapes of these eddies vary monotonically with viscosity ratio. For flows due to a single and a pair of stokeslets with the same strength, no eddy is noticed. However, a toroidal eddy appears in the case of a pair of stokelets with opposite strengths. The locations of the stokeslets and the viscosity ratio influence the eddy structure significantly.
Related Topics
Physical Sciences and Engineering Mathematics Mathematical Physics
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