AI Article Synopsis
- The study examines how a buoyant drop behaves and changes shape when suspended in a fluid that is flowing in a particular way (quadratic shearing) while considering small flow conditions.
- It utilizes a Navier slip condition to analyze the interface behavior, leading to new formulas for how the drop moves and deforms under different flow scenarios, such as sedimentation and Poiseuille flow.
- The findings reveal that interfacial slip has a significant impact on the drop's velocity and migration patterns, especially for drops with higher viscosity, and leads to quicker cross-stream movement and consistent behavior towards the centerline of the flow channel.
Article Abstract
We analyze the motion and deformation of a buoyant drop suspended in an unbounded fluid which is undergoing a quadratic shearing flow at small Reynolds number in the presence of slip at the interface of the drop. The boundary condition at the interface is accounted for by means of a simple Navier slip condition. Expressions for the velocity and the shape deformation of the drop are derived considering small but finite interface deformation, and results are presented for the specific cases of sedimentation, shear flow, and Poiseuille flow with previously reported results as the limiting cases of our general expressions. The presence of interfacial slip is found to markedly affect axial as well as cross-stream migration velocity of the drop in Poiseuille flow. The effect of slip is more prominent for drops with larger viscosity wherein the drop velocity increases. The presence of significant interface slippage always leads to migration of a deformed drop towards the centerline of the channel for any drop-to-medium viscosity ratio, which is in contrast to the case of no slip at the interface, which allows drop migration towards or away from the centerline depending on the viscosity ratio. We obtain the effect of slip on the cross-stream migration time scale, which quantifies the time required to reach a final steady radial position in the channel. The presence of slip at the drop interface leads to a decrease in the cross-stream migration time scale, which further results in faster motion of the drop in the cross-stream direction. Gravity in the presence of Poiseuille flow is shown to affect not only the axial motion, but also the cross-stream migration velocity of the drop; interfacial slip always increases the drop velocities.
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| http://dx.doi.org/10.1103/PhysRevE.92.023002 | DOI Listing |
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