Thermocapillary Thin Films: Periodic Steady States and Film Rupture

Abstract

We study stationary, periodic solutions to the thermocapillary thin-film model equation* ∂t h + ∂x (h3(∂x3 h - g∂x h) + Mh2(1+h)2∂xh) = 0, t>0,\ x∈ R, equation* which can be derived from the B\'enard-Marangoni problem via a lubrication approximation. When the Marangoni number M increases beyond a critical value M*, the constant solution becomes spectrally unstable via a (conserved) long-wave instability and periodic stationary solutions bifurcate. For a fixed period, we find that these solutions lie on a global bifurcation curve of stationary, periodic solutions with a fixed wave number and mass. Furthermore, we show that the stationary periodic solutions on the global bifurcation branch converge to a weak stationary periodic solution which exhibits film rupture. The proofs rely on a Hamiltonian formulation of the stationary problem and the use of analytic global bifurcation theory. Finally, we show the instability of the bifurcating solutions close to the bifurcation point and give a formal derivation of the amplitude equation governing the dynamics close to the onset of instability.