Rarefied gas correction for the bubble entrapment singularity in drop impacts

Laurent Duchemin; Christophe Josserand

doi:10.1016/j.crme.2012.10.028

Rarefied gas correction for the bubble entrapment singularity in drop impacts

Laurent Duchemin, Christophe Josserand

Research output: Contribution to journal › Short survey › peer-review

Abstract

We study the non-continuous correction in the dynamics of drop impact on a solid substrate. Close to impact, a thin film of gas is formed beneath the drop so that the local Knudsen number is of order one. We consider the first correction to the dynamics which consists of allowing slip of the gas along the substrate and the interface. We focus on the singular dynamics of entrapment that can be seen when surface tension and liquid viscosity can be neglected. There we show that different dynamical regimes are present that tend to lower the singularity strength. We finally suggest how these effects might be connected to the influence of the gas pressure in the impact dynamics observed in recent experiments.

Original language	English
Pages (from-to)	797-803
Number of pages	7
Journal	Comptes Rendus - Mecanique
Volume	340
Issue number	11-12
DOIs	https://doi.org/10.1016/j.crme.2012.10.028
Publication status	Published - 1 Nov 2012
Externally published	Yes

Keywords

Drop impact
Rarefied gas

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10.1016/j.crme.2012.10.028

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title = "Rarefied gas correction for the bubble entrapment singularity in drop impacts",

abstract = "We study the non-continuous correction in the dynamics of drop impact on a solid substrate. Close to impact, a thin film of gas is formed beneath the drop so that the local Knudsen number is of order one. We consider the first correction to the dynamics which consists of allowing slip of the gas along the substrate and the interface. We focus on the singular dynamics of entrapment that can be seen when surface tension and liquid viscosity can be neglected. There we show that different dynamical regimes are present that tend to lower the singularity strength. We finally suggest how these effects might be connected to the influence of the gas pressure in the impact dynamics observed in recent experiments.",

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T1 - Rarefied gas correction for the bubble entrapment singularity in drop impacts

AU - Duchemin, Laurent

AU - Josserand, Christophe

PY - 2012/11/1

Y1 - 2012/11/1

N2 - We study the non-continuous correction in the dynamics of drop impact on a solid substrate. Close to impact, a thin film of gas is formed beneath the drop so that the local Knudsen number is of order one. We consider the first correction to the dynamics which consists of allowing slip of the gas along the substrate and the interface. We focus on the singular dynamics of entrapment that can be seen when surface tension and liquid viscosity can be neglected. There we show that different dynamical regimes are present that tend to lower the singularity strength. We finally suggest how these effects might be connected to the influence of the gas pressure in the impact dynamics observed in recent experiments.

AB - We study the non-continuous correction in the dynamics of drop impact on a solid substrate. Close to impact, a thin film of gas is formed beneath the drop so that the local Knudsen number is of order one. We consider the first correction to the dynamics which consists of allowing slip of the gas along the substrate and the interface. We focus on the singular dynamics of entrapment that can be seen when surface tension and liquid viscosity can be neglected. There we show that different dynamical regimes are present that tend to lower the singularity strength. We finally suggest how these effects might be connected to the influence of the gas pressure in the impact dynamics observed in recent experiments.

KW - Drop impact

KW - Rarefied gas

U2 - 10.1016/j.crme.2012.10.028

DO - 10.1016/j.crme.2012.10.028

M3 - Short survey

AN - SCOPUS:84872425659

SN - 1631-0721

VL - 340

SP - 797

EP - 803

JO - Comptes Rendus - Mecanique

JF - Comptes Rendus - Mecanique

IS - 11-12

ER -

Rarefied gas correction for the bubble entrapment singularity in drop impacts

Abstract

Keywords

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