Non-Newtonian thin-film equations: global existence of solutions, gradient-flow structure and guaranteed lift-off

Abstract

We study the gradient-flow structure of a non-Newtonian thin film equation with power-law rheology. The equation is quasilinear, of fourth order and doubly-degenerate parabolic. By adding a singular potential to the natural Dirichlet energy, we introduce a modified version of the thin-film equation. Then, we set up a minimising-movement scheme that converges to global positive weak solutions to the modified problem. These solutions satisfy an energy-dissipation equality and follow a gradient flow. In the limit of a vanishing singularity of the potential, we obtain global non-negative weak solutions to the power-law thin-film equation equation* ∂t u + ∂x(m(u) |∂x3 u - G(u) ∂x u|α-1 (∂x3 u - G(u) ∂x u)) = 0 equation* with potential G in the shear-thinning (α > 1), Newtonian (α = 1) and shear-thickening case (0 <α < 1). The latter satisfy an energy-dissipation inequality. Finally, we derive dissipation bounds in the case G 0 which imply that solutions emerging from initial values with low energy lift up uniformly in finite time.