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Paper detail

Inverted Cheerios effect: Liquid drops attract or repel by elasto-capillarity

Solid particles floating at a liquid interface exhibit a long-ranged attraction mediated by surface tension. In the absence of bulk elasticity, this is the dominant lateral interaction of mechanical origin. Here we show that an analogous long-range interaction occurs between adjacent droplets on solid substrates, which crucially relies on a combination of capillarity and bulk elasticity. We experimentally observe the interaction between droplets on soft gels and provide a theoretical framework that quantitatively predicts the migration velocity of the droplets. Remarkably, we find that while on thick substrates the interaction is purely attractive and leads to drop-drop coalescence, for relatively thin substrates a short-range repulsion occurs which prevents the two drops from coming into direct contact. This versatile, new interaction is the liquid-on-solid analogue of the "Cheerios effect". The effect will strongly influence the condensation and coarsening of drop soft polymer films, and has potential implications for colloidal assembly and in mechanobiology.

preprint2016arXivOpen access
S. KarpitschkaA. PandeyL. A. LubbersJ. H. WeijsL. BottoS. DasB. AndreottiJ. H. Snoeijer
cond-mat.softphysics.flu-dyn
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S. KarpitschkaA. PandeyL. A. LubbersJ. H. WeijsL. BottoS. DasB. AndreottiJ. H. Snoeijer

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