Interplay between viscosity and elasticity in freely expanding liquid sheets

TL;DR

This study explores how viscosity and elasticity influence the expansion dynamics of liquid sheets formed by impacting drops, revealing different behaviors depending on the fluid's relaxation time relative to the sheet's lifetime.

Contribution

It demonstrates the interplay between viscous and elastic effects in liquid sheet expansion and introduces a model linking maximal expansion to fluid viscosity and rheological properties.

Findings

Viscoelastic fluids with short relaxation times behave like Newtonian fluids with similar viscosity.

Maximal expansion decreases with increasing viscosity for low-viscosity samples.

Longer relaxation times lead to enhanced, heterogeneous expansion with crack formation.

Abstract

We investigate the dynamics of freely expanding liquid sheets prepared with fluids with different rheological properties, (i) viscous fluids with a zero-shear viscosity $\eta_0$ in the range $(1-1000) \, \mathrm{mPa.s}$ and (ii) viscoelastic Maxwell fluids whose elastic modulus, $G_0$, characteristic relaxation time, $\tau$, and zero-shear viscosity, $\eta_0=G_0 \tau$, can be tuned over several orders of magnitude. The sheets are produced by impacting a drop of fluid on a small cylindrical solid target. For viscoelastic fluids, we show that, when $\tau$ is shorter than the typical lifetime of the sheet ($\sim 10$ ms), the dynamics of the sheet is similar to that of Newtonian viscous liquids with equal zero-shear viscosity. In that case, for little viscous samples ($\eta_0 <\sim 30$ mPa.s), the maximal expansion of the sheet, $d_{\rm{max}}$, is independent of $\eta_0$, whereas for more viscous samples, $d_{\rm{max}}$ decreases as $\eta_0$ increases. We provide a simple model to account for the dependence of the maximal expansion of the sheet with the viscosity that is based on an energy balance between inertia, surface tension and viscous shear dissipation on the solid target, and which accounts well for our experimental data. By contrast, when $\tau$ is longer than the typical lifetime of the sheet, the behavior drastically differs. The sheet expansion is strongly enhanced as compared to that of viscous samples with comparable zero-shear viscosity, but is heterogeneous with the occurrence of cracks, revealing the elastic nature of the viscoelastic fluid.