Droplet impact on a thin liquid film: Anatomy of the splash

Christophe Josserand; Pascal Ray; Stéphane Zaleski

doi:10.1017/jfm.2016.468

Droplet impact on a thin liquid film: Anatomy of the splash

Christophe Josserand
, Pascal Ray
, Stéphane Zaleski

Résultats de recherche: Contribution à un journal › Article › Revue par des pairs

Résumé

We investigate the dynamics of drop impact on a thin liquid film at short times in order to identify the mechanisms of splash formation. Using numerical simulations and scaling analysis, we show that it depends both on the inertial dynamics of the liquid and the cushioning of the gas. Two asymptotic regimes are identified, characterized by a new dimensionless number : when the gas cushioning is weak, the jet is formed after a sequence of bubbles are entrapped and the jet speed is mostly selected by the Reynolds number of the impact. On the other hand, when the air cushioning is important, the lubrication of the gas beneath the drop and the liquid film controls the dynamics, leading to a single bubble entrapment and a weaker jet velocity.

langue originale	Anglais
Pages (de - à)	775-805
Nombre de pages	31
journal	Journal of Fluid Mechanics
Volume	802
Les DOIs	https://doi.org/10.1017/jfm.2016.468
état	Publié - 10 sept. 2016
Modification externe	Oui

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title = "Droplet impact on a thin liquid film: Anatomy of the splash",

abstract = "We investigate the dynamics of drop impact on a thin liquid film at short times in order to identify the mechanisms of splash formation. Using numerical simulations and scaling analysis, we show that it depends both on the inertial dynamics of the liquid and the cushioning of the gas. Two asymptotic regimes are identified, characterized by a new dimensionless number : when the gas cushioning is weak, the jet is formed after a sequence of bubbles are entrapped and the jet speed is mostly selected by the Reynolds number of the impact. On the other hand, when the air cushioning is important, the lubrication of the gas beneath the drop and the liquid film controls the dynamics, leading to a single bubble entrapment and a weaker jet velocity.",

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author = "Christophe Josserand and Pascal Ray and St{\'e}phane Zaleski",

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AU - Josserand, Christophe

AU - Ray, Pascal

AU - Zaleski, Stéphane

PY - 2016/9/10

Y1 - 2016/9/10

N2 - We investigate the dynamics of drop impact on a thin liquid film at short times in order to identify the mechanisms of splash formation. Using numerical simulations and scaling analysis, we show that it depends both on the inertial dynamics of the liquid and the cushioning of the gas. Two asymptotic regimes are identified, characterized by a new dimensionless number : when the gas cushioning is weak, the jet is formed after a sequence of bubbles are entrapped and the jet speed is mostly selected by the Reynolds number of the impact. On the other hand, when the air cushioning is important, the lubrication of the gas beneath the drop and the liquid film controls the dynamics, leading to a single bubble entrapment and a weaker jet velocity.

AB - We investigate the dynamics of drop impact on a thin liquid film at short times in order to identify the mechanisms of splash formation. Using numerical simulations and scaling analysis, we show that it depends both on the inertial dynamics of the liquid and the cushioning of the gas. Two asymptotic regimes are identified, characterized by a new dimensionless number : when the gas cushioning is weak, the jet is formed after a sequence of bubbles are entrapped and the jet speed is mostly selected by the Reynolds number of the impact. On the other hand, when the air cushioning is important, the lubrication of the gas beneath the drop and the liquid film controls the dynamics, leading to a single bubble entrapment and a weaker jet velocity.

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JO - Journal of Fluid Mechanics

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Droplet impact on a thin liquid film: Anatomy of the splash

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