Retraction Dynamics of a Highly Viscous Liquid Sheet

Abstract

We study the one-dimensional capillary-driven retraction of a finite, planar liquid sheet in the asymptotic regime where both the Ohnesorge number Oh and the initial length-to-thickness ratio l0/h0 are large. In this regime, the fluid domain decomposes into two regions: a thin-film region governed by one-dimensional mass and momentum equations, and a small tip region near the free edge described by a self-similar Stokes flow. Asymptotic matching between these regions yields an effective boundary condition for the thin-film region, representing a balance between viscous and capillary forces at the free edge. Surface tension drives the thin-film flow only through this boundary condition, while the local momentum balance is dominated by viscous and inertial stresses. We show that the thin-film flow possesses a conserved quantity, reducing the equation of thickness to heat equation with time-dependent boundary conditions. The reduced problem depends on a single dimensionless parameter L = l0 / (4 h0 Oh). Numerical solutions of the reduced model agree well with previous studies and reveal that the sheet undergoes distinct retraction regimes depending on L and a dimensionless time after rupture T. We derive asymptotic approximations for the thickness profile, velocity profile, and retraction speed during the early and late stages of retraction. At early times, the retraction speed grows as T1/2, while at late times it decays as 1/T2. An intermediate regime arises for very long sheets (L 1). During this phase, the retraction speed approaches the Taylor-Culick value. When T ≈ L, the speed undergoes fast deceleration from the Taylor-Culick speed to late-time asymptotics.