Drop dynamics after impact on a solid wall: Theory and simulations

Jens Eggers; Marco A. Fontelos; Christophe Josserand; Stéphane Zaleski

doi:10.1063/1.3432498

Drop dynamics after impact on a solid wall: Theory and simulations

Jens Eggers
, Marco A. Fontelos
, Christophe Josserand
, Stéphane Zaleski

Research output: Contribution to journal › Article › peer-review

Abstract

We study the impact of a fluid drop onto a planar solid surface at high speed so that at impact, kinetic energy dominates over surface energy and inertia dominates over viscous effects. As the drop spreads, it deforms into a thin film, whose thickness is limited by the growth of a viscous boundary layer near the solid wall. Owing to surface tension, the edge of the film retracts relative to the flow in the film and fluid collects into a toroidal rim bounding the film. Using mass and momentum conservation, we construct a model for the radius of the deposit as a function of time. At each stage, we perform detailed comparisons between theory and numerical simulations of the Navier-Stokes equation.

Original language	English
Article number	033005PHF
Pages (from-to)	-13
Number of pages	1
Journal	Physics of Fluids
Volume	22
Issue number	6
DOIs	https://doi.org/10.1063/1.3432498
Publication status	Published - 1 Jan 2010
Externally published	Yes

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10.1063/1.3432498

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abstract = "We study the impact of a fluid drop onto a planar solid surface at high speed so that at impact, kinetic energy dominates over surface energy and inertia dominates over viscous effects. As the drop spreads, it deforms into a thin film, whose thickness is limited by the growth of a viscous boundary layer near the solid wall. Owing to surface tension, the edge of the film retracts relative to the flow in the film and fluid collects into a toroidal rim bounding the film. Using mass and momentum conservation, we construct a model for the radius of the deposit as a function of time. At each stage, we perform detailed comparisons between theory and numerical simulations of the Navier-Stokes equation.",

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AU - Zaleski, Stéphane

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AB - We study the impact of a fluid drop onto a planar solid surface at high speed so that at impact, kinetic energy dominates over surface energy and inertia dominates over viscous effects. As the drop spreads, it deforms into a thin film, whose thickness is limited by the growth of a viscous boundary layer near the solid wall. Owing to surface tension, the edge of the film retracts relative to the flow in the film and fluid collects into a toroidal rim bounding the film. Using mass and momentum conservation, we construct a model for the radius of the deposit as a function of time. At each stage, we perform detailed comparisons between theory and numerical simulations of the Navier-Stokes equation.

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Drop dynamics after impact on a solid wall: Theory and simulations

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