Abstract
Analytical solutions are found for both longitudinal and transverse shear flow, at zero Reynolds number, over immobilized superhydrophobic surfaces comprising a periodic array of near-circular menisci penetrating into a no-slip surface and where the menisci are no longer shear-free but are taken to be no-slip zones. Explicit formulae for the associated longitudinal and transverse effective slip lengths are derived; these are then compared with analogous results for superhydrophobic surfaces of the same characteristic geometry but where the menisci are shear-free. The new formulae give results that are consistent with recent experimental observations that have prompted suggestions that menisci that are assumed to be free of shear have in fact been immobilized. Significantly, for transverse shear flow, it is found that at critical downward meniscus protrusion angles of around$47^{\circ }$, for many surface geometries, it is impossible to distinguish, purely from the effective slip length, between a no-shear and a no-slip boundary condition. We also find that immobilized menisci bowing into the grooves at supercritical angles just below$90^{\circ }$can be almost twice as slippery to transverse shear as no-shear menisci. The results are relevant to recent discussion as to whether surface immobilization, due to contamination by surfactants or other physical mechanisms, is compromising drag reduction properties expected from an assumed no-shear condition.
Highlights
The purpose of this paper is to offer complementary theoretical insights into the question of which surface condition is active on curved menisci in unidirectional superhydrophobic surfaces: an explicit comparison of the effective slip lengths for both no-shear and no-slip boundary conditions in longitudinal and transverse shear flows is performed
No-slip surface x meniscus happens to be a no-slip surface – that is, it has been immobilized by some means – we are equivalently dealing with a corrugated no-slip wall with circulararc ‘riblets’, and it is more common to refer to these effective slip lengths as protrusion heights (Bechert & Bartenwerfer 1989; Luchini, Manzo & Pozzi 1991)
Since the consensus in much previous work has been that the menisci in superhydrophobic surfaces are close to shear-free, there has been great effort in seeking to quantify the effective slip properties under a shear-free assumption
Summary
Meniscus happens to be a no-slip surface – that is, it has been immobilized by some means – we are equivalently dealing with a corrugated no-slip wall with circulararc ‘riblets’, and it is more common to refer to these effective slip lengths as protrusion heights (Bechert & Bartenwerfer 1989; Luchini, Manzo & Pozzi 1991) In the latter context, since the choice of the y-origin is arbitrary, the only physically significant quantity is the difference λ|| − λ⊥, which is independent of the choice of y-origin, and quantifies how much a corrugated no-slip wall impedes a transverse shear relative to a longitudinal shear.
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