Early Stages of Drop Coalescence

Antoine Deblais; Kaili Xie; Peter  Lewin-Jones; Dirk Aarts; Miguel Angel  Herrada; Jens G Eggers; James Sprittles; Daniel  Bonn

doi:10.48550/arXiv.2402.00500

Early Stages of Drop Coalescence

Antoine Deblais^*, Kaili Xie^*, Peter Lewin-Jones, Dirk Aarts, Miguel Angel Herrada, Jens G Eggers, James Sprittles, Daniel Bonn

^*Corresponding author for this work

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Abstract

Despite the large body of research on coalescence, firm agreement between experiment, theory, and compu- tation has not been established for the very earliest times following the initial contact of two liquid volumes. Combining a range of experimental and computational modelling approaches, we have been able to elucidate the influence of the intervening gas, of the van der Waals forces and of thermal fluctuations on coalescence. For simple liquids, the gas influences both pre- and post-contact regimes, with a jump-to-contact the primary mode of merging. Subsequently, wave-like air pockets are observed. For a system with ultralow interfacial tension, that mimics nanodrop behaviour, the very first moments are governed by thermal fluctuations at the interfaces, with a nontrivial opening speed given by stochastic thermally driven motion.

Original language	English
Article number	L042001
Number of pages	12
Journal	Physical Review Letters
DOIs	https://doi.org/10.48550/arXiv.2402.00500
Publication status	Published - 10 Apr 2025

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title = "Early Stages of Drop Coalescence",

abstract = "Despite the large body of research on coalescence, firm agreement between experiment, theory, and compu- tation has not been established for the very earliest times following the initial contact of two liquid volumes. Combining a range of experimental and computational modelling approaches, we have been able to elucidate the influence of the intervening gas, of the van der Waals forces and of thermal fluctuations on coalescence. For simple liquids, the gas influences both pre- and post-contact regimes, with a jump-to-contact the primary mode of merging. Subsequently, wave-like air pockets are observed. For a system with ultralow interfacial tension, that mimics nanodrop behaviour, the very first moments are governed by thermal fluctuations at the interfaces, with a nontrivial opening speed given by stochastic thermally driven motion.",

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AU - Deblais, Antoine

AU - Xie, Kaili

AU - Lewin-Jones, Peter

AU - Aarts, Dirk

AU - Herrada, Miguel Angel

AU - Eggers, Jens G

AU - Sprittles, James

AU - Bonn, Daniel

PY - 2025/4/10

Y1 - 2025/4/10

N2 - Despite the large body of research on coalescence, firm agreement between experiment, theory, and compu- tation has not been established for the very earliest times following the initial contact of two liquid volumes. Combining a range of experimental and computational modelling approaches, we have been able to elucidate the influence of the intervening gas, of the van der Waals forces and of thermal fluctuations on coalescence. For simple liquids, the gas influences both pre- and post-contact regimes, with a jump-to-contact the primary mode of merging. Subsequently, wave-like air pockets are observed. For a system with ultralow interfacial tension, that mimics nanodrop behaviour, the very first moments are governed by thermal fluctuations at the interfaces, with a nontrivial opening speed given by stochastic thermally driven motion.

AB - Despite the large body of research on coalescence, firm agreement between experiment, theory, and compu- tation has not been established for the very earliest times following the initial contact of two liquid volumes. Combining a range of experimental and computational modelling approaches, we have been able to elucidate the influence of the intervening gas, of the van der Waals forces and of thermal fluctuations on coalescence. For simple liquids, the gas influences both pre- and post-contact regimes, with a jump-to-contact the primary mode of merging. Subsequently, wave-like air pockets are observed. For a system with ultralow interfacial tension, that mimics nanodrop behaviour, the very first moments are governed by thermal fluctuations at the interfaces, with a nontrivial opening speed given by stochastic thermally driven motion.

U2 - 10.48550/arXiv.2402.00500

DO - 10.48550/arXiv.2402.00500

M3 - Article (Academic Journal)

SN - 0031-9007

JO - Physical Review Letters

JF - Physical Review Letters

M1 - L042001

ER -

Early Stages of Drop Coalescence

Abstract

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