Sharp threshold for a one-dimensional thin film equation in the supercritical case

Abstract

We study a one-dimensional thin film equation combining competitive effects of aggregation and repulsion, where repulsion is modeled by fourth-order diffusion and aggregation by backward second-order degenerate diffusion with exponent m>0. Under natural regularity constraints, we prove that for every m>0, there exists a unique (up to the mass-critical case m=3) nonnegative, radially decreasing steady state U* which coincides with the extremal function of the sharp Sz.-Nagy inequality and is simultaneously the global minimizer of the free energy. Using this variational characterization in the supercritical regime 3<m<∞, we show that finite-time blow-up occurs for all initial data whose initial free energy lies below the positive threshold F(U*), provided the Lm+1-norm of the initial datum exceeds that of U*. Conversely, if the Lm+1-norm is below that of U*, the solution exists globally and its second moment diverges as t∞. This sharp criterion significantly extends the previously known blow-up condition requiring negative free energy to a much wider class of initial data (see BP00). Our results identify the steady state U* as the critical pivot linking variational structure to dynamical behavior, and provide a constructive method to determine blow-up versus global existence via an explicit Lm+1-norm comparison.