Surfactant-induced dissipation in sheared foams: Mechanics and thermodynamics

Yedhir Mezache; François Detcheverry; Bastien Di Pierro; Peter D.M. Spelt; Anne Laure Biance; Marie Le Merrer

doi:10.1103/PhysRevFluids.9.094008

Surfactant-induced dissipation in sheared foams: Mechanics and thermodynamics

Yedhir Mezache
, François Detcheverry
, Bastien Di Pierro
, Peter D.M. Spelt
, Anne Laure Biance
, Marie Le Merrer

IGFL, Université de Lyon, Université Lyon 1

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

Abstract

Though the influence of surfactant type on foam rheological properties is well established experimentally, the underlying physical mechanisms are far from understood. Here, using fully resolved numerical simulation of an elementary T1 event taking into account both flow and surfactant dynamics, we unveil the origin of surfactant-induced dissipation in sheared foams. To model the diffusive and exchange contributions, we revisit the classical Lucassen model by switching from a mechanical to a thermodynamic perspective, and we find that in spite of its extreme simplicity, it captures well some behaviors of our numerical foam. Our approach should be useful in the class of surfactant-controlled systems, from soap films and emulsions to coating films and spreading droplets.

Original language	English
Article number	094008
Journal	Physical Review Fluids
Volume	9
Issue number	9
DOIs	https://doi.org/10.1103/PhysRevFluids.9.094008
Publication status	Published - 1 Sept 2024
Externally published	Yes

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10.1103/PhysRevFluids.9.094008

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title = "Surfactant-induced dissipation in sheared foams: Mechanics and thermodynamics",

abstract = "Though the influence of surfactant type on foam rheological properties is well established experimentally, the underlying physical mechanisms are far from understood. Here, using fully resolved numerical simulation of an elementary T1 event taking into account both flow and surfactant dynamics, we unveil the origin of surfactant-induced dissipation in sheared foams. To model the diffusive and exchange contributions, we revisit the classical Lucassen model by switching from a mechanical to a thermodynamic perspective, and we find that in spite of its extreme simplicity, it captures well some behaviors of our numerical foam. Our approach should be useful in the class of surfactant-controlled systems, from soap films and emulsions to coating films and spreading droplets.",

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AU - Mezache, Yedhir

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AU - Spelt, Peter D.M.

AU - Biance, Anne Laure

AU - Le Merrer, Marie

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AB - Though the influence of surfactant type on foam rheological properties is well established experimentally, the underlying physical mechanisms are far from understood. Here, using fully resolved numerical simulation of an elementary T1 event taking into account both flow and surfactant dynamics, we unveil the origin of surfactant-induced dissipation in sheared foams. To model the diffusive and exchange contributions, we revisit the classical Lucassen model by switching from a mechanical to a thermodynamic perspective, and we find that in spite of its extreme simplicity, it captures well some behaviors of our numerical foam. Our approach should be useful in the class of surfactant-controlled systems, from soap films and emulsions to coating films and spreading droplets.

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Surfactant-induced dissipation in sheared foams: Mechanics and thermodynamics

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