What question did this study set out to answer?

To develop a model for understanding the impact dynamics of viscous drops on non-wetting substrates.

February 13, 2026

Liquid Hertz impact: Low-Weber non-wetting drop dynamics

Key Points

To develop a model for understanding the impact dynamics of viscous drops on non-wetting substrates.
Formulated a quasi-static model for drop impact
Described drop deformation using the Young-Laplace equation
Included a damping coefficient for viscous dissipation
Evaluated drop characteristics at low Weber numbers
Compared model predictions with experimental data
The model accurately captures drop spreading factors at low Weber numbers
Predictions match experimental data for viscously damped impacts
Provided new insights into the dynamics of liquid drop interactions on surfaces

Abstract

A quasi-static model for the normal impact of a viscous drop on a non-wetting substrate is developed. The axisymmetric deformation of a sessile drop is described analytically using new asymptotically exact approximations to solutions of the Young-Laplace equation. Viscous dissipation is accounted for in linearized form through a damping coefficient inversely proportional to the relaxation time of small-amplitude oscillations of a viscous sessile drop. This formulation enables evaluation of the key characteristics of Hertz-type impact at low Weber numbers, including the drop spreading factor, restitution coefficient, and characteristic time scale. Comparison with experimental data demonstrates that the model reliably captures the essential features of slow, viscously damped liquid drop impacts on non-wetting surfaces.

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Liquid Hertz impact: Low-Weber non-wetting drop dynamics

Key Points

Abstract

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