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Paper detail

Quantifying effective slip length over micropatterned hydrophobic surfaces

We employ micro-particle image velocimetry ($μ$-PIV) to investigate laminar micro-flows in hydrophobic microstructured channels, in particular the slip length. These microchannels consist of longitudinal micro-grooves, which can trap air and prompt a shear-free boundary condition and thus slippage enhancement. Our measurements reveal an increase of the slip length when the width of the micro-grooves is enlarged. The result of the slip length is smaller than the analytical prediction by Philip et al. [1] for an infinitely large and textured channel comprised of alternating shear-free and no-slip boundary conditions. The smaller slip length (as compared to the prediction) can be attributed to the confinement of the microchannel and the bending of the meniscus (liquid-gas interface). Our experimental studies suggest that the curvature of the meniscus plays an important role in microflows over hydrophobic micro-ridges.

preprint2009arXivOpen access
Peichun TsaiAlisia M. PetersChristophe PiratMatthias WesslingRob G. H. LammertinkDetlef Lohse
physics.flu-dyn
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Peichun TsaiAlisia M. PetersChristophe PiratMatthias WesslingRob G. H. LammertinkDetlef Lohse

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