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Microscopic Origin of Capillary Force Balance at Contact Line

JingCun Fan, J. De Coninck, HengAn Wu, Fengchao Wang

2020Physical Review Letters114 citationsDOI

Abstract

We investigate the underlying mechanism of capillary force balance at the contact line. In particular, we offer a novel approach to describe and quantify the capillary force on the liquid in coexistence with its vapor phase, which is crucial in wetting and spreading dynamics. Its relation with the interface tension is elucidated. The proposed model is verified by our molecular dynamics simulations over a wide contact angle range. Differences in capillary forces are observed in evaporating droplets on homogeneous and decorated surfaces. Our findings not only provide a theoretical insight into capillary forces at the contact line, but also validate Young's equation based on a mechanical interpretation.

Topics & Concepts

Capillary actionWettingContact angleSurface tensionMaterials scienceCapillary numberMechanicsForce balanceMolecular dynamicsTension (geology)HomogeneousLine (geometry)Contact forceBalance (ability)Chemical physicsPhysicsClassical mechanicsThermodynamicsComposite materialMathematicsGeometryMedicineUltimate tensile strengthPhysical medicine and rehabilitationQuantum mechanicsSurface Modification and SuperhydrophobicityNanomaterials and Printing TechnologiesFluid Dynamics and Heat Transfer
Microscopic Origin of Capillary Force Balance at Contact Line | Litcius