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Workshop

Classical solutions to the thin-film equation with general mobility in the perfect-wetting regime

  • Anouk Wisse (TU Delft)
E1 05 (Leibniz-Saal)

Abstract

We prove well-posedness, partial regularity, and stability of the thin-film equation with general mobility m(h) = h^n and mobility exponent n in the union of (1,3/2) and (3/2,3) in the regime of perfect wetting (zero contact angle). After a suitable coordinate transformation to fix the free boundary (the contact line where liquid, air, and solid coalesce), the thin-film equation is rewritten as an abstract Cauchy problem and we obtain maximal L^p_t regularity for the linearized evolution. Partial regularity close to the free boundary is obtained by studying the elliptic regularity of the spatial part of the linearization. This yields solutions that are non-smooth in the distance to the free boundary, in line with previous findings for source-type self-similar solutions. In a scaling-wise quasi-minimal norm for the initial data, we obtain a well-posedness and asymptotic stability result for perturbations of traveling waves. The novelty of this work lies in the usage of L^p-estimates in time, where p is between one and infinity, while the existing literature mostly deals with p = 2 at least for nonlinear mobilities. This turns out to be essential to obtain for the first time a well-posedness result in the perfect-wetting regime for all physical nonlinear slip conditions except for a strongly degenerate case at n = 3/2 and the well-understood Greenspan-slip case n = 1.

Katja Heid

Max Planck Institute for Mathematics in the Sciences Contact via Mail

Lorenzo Giacomelli

Sapienza Università di Roma

Hans Knüpfer

Ruprecht-Karls-Universität Heidelberg

Felix Otto

Max Planck Institute for Mathematics in the Sciences

Christian Seis

Universität Münster