Inviscid coalescence of drops

L. Duchemin; J. Eggers; C. Josserand

doi:10.1017/S0022112003004646

Inviscid coalescence of drops

L. Duchemin, J. Eggers, C. Josserand

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

Abstract

We study the coalescence of two drops of an ideal fluid driven by surface tension. The velocity of approach is taken to be zero and the dynamical effect of the outer fluid (usually air) is neglected. Our approximation is expected to be valid on scales larger than ℓ_ν = ρν²/σ, which is 10 nm for water. Using a high-precision boundary integral method, we show that the walls of the thin retracting sheet of air between the drops reconnect in finite time to form a toroidal enclosure. After the initial reconnection, retraction starts again, leading to a rapid sequence of enclosures. Averaging over the discrete events, we find the minimum radius of the liquid bridge connecting the two drops to scale like r_b ∝ t^1/2.

Original language	English
Pages (from-to)	167-178
Number of pages	12
Journal	Journal of Fluid Mechanics
Volume	487
DOIs	https://doi.org/10.1017/S0022112003004646
Publication status	Published - 25 Jul 2003
Externally published	Yes

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title = "Inviscid coalescence of drops",

abstract = "We study the coalescence of two drops of an ideal fluid driven by surface tension. The velocity of approach is taken to be zero and the dynamical effect of the outer fluid (usually air) is neglected. Our approximation is expected to be valid on scales larger than ℓν = ρν2/σ, which is 10 nm for water. Using a high-precision boundary integral method, we show that the walls of the thin retracting sheet of air between the drops reconnect in finite time to form a toroidal enclosure. After the initial reconnection, retraction starts again, leading to a rapid sequence of enclosures. Averaging over the discrete events, we find the minimum radius of the liquid bridge connecting the two drops to scale like rb ∝ t1/2.",

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AU - Duchemin, L.

AU - Eggers, J.

AU - Josserand, C.

PY - 2003/7/25

Y1 - 2003/7/25

N2 - We study the coalescence of two drops of an ideal fluid driven by surface tension. The velocity of approach is taken to be zero and the dynamical effect of the outer fluid (usually air) is neglected. Our approximation is expected to be valid on scales larger than ℓν = ρν2/σ, which is 10 nm for water. Using a high-precision boundary integral method, we show that the walls of the thin retracting sheet of air between the drops reconnect in finite time to form a toroidal enclosure. After the initial reconnection, retraction starts again, leading to a rapid sequence of enclosures. Averaging over the discrete events, we find the minimum radius of the liquid bridge connecting the two drops to scale like rb ∝ t1/2.

AB - We study the coalescence of two drops of an ideal fluid driven by surface tension. The velocity of approach is taken to be zero and the dynamical effect of the outer fluid (usually air) is neglected. Our approximation is expected to be valid on scales larger than ℓν = ρν2/σ, which is 10 nm for water. Using a high-precision boundary integral method, we show that the walls of the thin retracting sheet of air between the drops reconnect in finite time to form a toroidal enclosure. After the initial reconnection, retraction starts again, leading to a rapid sequence of enclosures. Averaging over the discrete events, we find the minimum radius of the liquid bridge connecting the two drops to scale like rb ∝ t1/2.

U2 - 10.1017/S0022112003004646

DO - 10.1017/S0022112003004646

M3 - Article

AN - SCOPUS:0042732017

SN - 0022-1120

VL - 487

SP - 167

EP - 178

JO - Journal of Fluid Mechanics

JF - Journal of Fluid Mechanics

ER -

Inviscid coalescence of drops

Abstract

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