Activity-Driven Dewetting and Rupture in Thin Liquid Films

TL;DR

This paper demonstrates how internal activity in thin liquid films alters classical dewetting behavior, leading to new instability mechanisms and growth dynamics driven by active stresses and persistence, relevant to biological materials.

Contribution

It introduces a minimal microscopic model showing how activity fundamentally changes dewetting dynamics, creating two regulated length scales and modifying growth laws.

Findings

Active stresses compete with adhesion to produce two length scales.

Activity shifts growth from diffusion-controlled to persistence-driven.

Rupture front accelerates towards ballistic propagation.

Abstract

Thin-film dewetting is classically governed by an adhesion-mediated spinodal instability in which curvature-driven diffusion controls post-rupture coarsening. We show that internal activity fundamentally restructures this instability. Using a minimal microscopic model of an active liquid film on a solid substrate, we identify a competition between active stresses and film-substrate adhesion that produces two independently regulated dynamical length scales: vertical liquid accumulation and lateral rupture propagation. While passive films exhibit universal diffusion-limited growth, $\ell_z(t)\sim t^{1/3}$, activity converts transport from curvature-controlled diffusion to persistence-driven motion, yielding a continuous increase of the coarsening exponent from $\approx 0.33$ to $\approx 0.6$. The growth law analysis shows that persistent self-propulsion introduces an advective flux that competes with curvature-induced chemical potential gradients, enhancing growth when the persistence length becomes comparable to the evolving domain size. Simultaneously, the rupture front transitions from dissipative spreading to strongly accelerated propagation approaching ballistic scaling. This decoupling shows that activity does not simply renormalize effective surface forces but generates a distinct nonequilibrium interfacial instability governed by the balance between persistence length and adhesion. The results provide a minimal physical mechanism linking classical thin-film dewetting to dewetting-like rupture observed in active and biological materials.