The Cox-Voinov law for traveling waves in the partial wetting regime

Abstract

We consider the thin-film equation ∂t h + ∂y (m(h) ∂y3 h) = 0 in \h > 0\ with partial-wetting boundary conditions and inhomogeneous mobility of the form m(h) = h3+λ3-nhn, where h 0 is the film height, λ > 0 is the slip length, y > 0 denotes the lateral variable, and n ∈ (0,3) is the mobility exponent parameterizing the nonlinear slip condition. The partial-wetting regime implies the boundary condition ∂y h = const. > 0 at the triple junction ∂\h > 0\ (nonzero microscopic contact angle). Existence and uniqueness of traveling-wave solutions to this problem under the constraint ∂y2 h 0 as h ∞ have been proved in previous work by Chiricotto and Giacomelli in [Commun. Appl. Ind. Math., 2(2):e-388, 16, 2011]. We are interested in the asymptotics as h 0 and h ∞. By reformulating the problem as h 0 as a dynamical system for the difference between the solution and the microscopic contact angle, values for n are found for which linear as well as nonlinear resonances occur. These resonances lead to a different asymptotic behavior of the solution as h0 depending on n. Together with the asymptotics as h∞ characterizing the Cox-Voinov law for the velocity-dependent macroscopic contact angle as found by Giacomelli, the first author of this work, and Otto in [Nonlinearity, 29(9):2497-2536, 2016], the rigorous asymptotics of traveling-wave solutions to the thin-film equation in partial wetting can be characterized. Furthermore, our approach enables us to analyze the relation between the microscopic and macroscopic contact angle. It is found that the Cox-Voinov law for the macroscopic contact angle depends continuously differentiably on the microscopic contact angle.