Theoretical models for the stability of a liquid ring on a substrate

J. DIEZ; A. G. GONZÁ LEZ; Y. WU; J. D. FOWLKES; P. RACK; L. KONDIC

Pittsburgh, Pennsylvania

Congreso; 66th Annual Meeting of Division of Fluid Dynamics (DFD) of the American Physical Society (APS); 2013

Division of Fluid Dynamics (DFD) of the American Physical Society (APS)

A viscous incompressible fluid ring on a partially wetting substrate is studied within the framework of long-wave theory. We found that static equilibria are posible in the presence of contact angle hysteresis. Their linear stability is carried out by using a slip model. A quasi-static approximation is also implemented to analyze longer times. This latter approach takes into account the concomitant variation of the instantaneous growth rates of the modes responsible for either collapse of the ring into a single central drop or breakup into a number of droplets along the ring circumforence. We compare the results of these models with those obtained from nonlinear numerical simulations based on a complementary disjoining pressure model. We find remarkably good agreement regarding the expected number of drops forming during the breakup process. (J. Fluid Mech. 718, 246 (2013))