Unifying theory of scaling in drop impact: Forces & maximum spreading diameter

TL;DR

This paper develops a unifying theoretical framework, inspired by turbulence theory, to predict how droplet impact force and spreading diameter depend on velocity, size, and viscosity across a wide parameter range.

Contribution

It introduces a novel energy dissipation splitting approach that accurately models impact dynamics over extensive Weber and Ohnesorge number ranges.

Findings

The theory quantitatively matches experimental data for impact force and spreading.

Viscous dissipation is significant even in low-viscosity impacts.

The approach unifies understanding of impact behavior across diverse conditions.

Abstract

The dynamics of drop impact on a rigid surface -- omnipresent in nature and technology -- strongly depends on the droplet's velocity, its size, and its material properties. The main characteristics are the droplet's force exerted on the surface and its maximal spreading radius. The crucial question is: How do they depend on the (dimensionless) control parameters, which are the Weber number $We$ (non-dimensionalized kinetic energy) and the Ohnesorge number $Oh$ (dimensionless viscosity)? Here we perform direct numerical simulations over the huge parameter range $1\le We \le 10^3$ and $10^{-3}\le Oh \le 10^2$ and in particular develop a unifying theoretical approach, which is inspired by the Grossmann-Lohse theory for wall-bounded turbulence [J. Fluid Mech. 407, 27 (2000); PRL 86, 3316 (2001)]. The key idea is to split the energy dissipation rate into the different phases of the impact process, in which different physical mechanisms dominate. The theory can consistently and quantitatively account for the $We$ and $Oh$ dependences of the maximal impact force and the maximal spreading diameter over the huge parameter space. It also clarifies why viscous dissipation plays a significant role during impact, even for low-viscosity droplets (low $Oh$), in contrast to what had been assumed in prior theories.