Detachment of Oil Drops from Solid Surfaces in Surfactant Solutions:  Molecular Mechanisms at a Moving Contact Line

Kralchevsky, Peter A.; Danov, Krassimir D.; Kolev, Vesselin; Gurkov, Theodor D.; Temelska, M.I.; Brenn, Günter

doi:10.1021/ie049211t

Cited by 52 publications

(17 citation statements)

References 51 publications

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“…Discrepancies between these theoretical predictions and the experimental data have been found, particularly for systems containing a wide spectrum of contact line speed. [20][21][22][23][24][25][26] This suggests that neither model is complete in the description of the energy dissipation.…”

Section: Introductionmentioning

confidence: 99%

Continuum models for the contact line problem

2010

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Continuum models are derived for the moving contact line problem through a combination of macroscopic and microscopic considerations. Macroscopic thermodynamic argument is used to place constraints on the form of the boundary conditions at the solid surface and the contact line. This information is then used to set up molecular dynamics to measure the detailed functional dependence of the boundary conditions. Long range molecular forces are taken into account in the form of a surface potential. This allows us to handle the case of complete wetting as well as the case of partial wetting. In particular, we obtain a new continuum model for both cases in a unified form. Two main parameters and different spreading regimes are identified from the analysis of the energy dissipations for the continuum model. Scaling laws in these different regimes are derived. The new continuum model also allows us to derive boundary conditions for the lubrication approximation. Numerical results are presented for the thin film model, and the effect of the boundary condition is investigated.

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Section: Introductionmentioning

confidence: 99%

Continuum models for the contact line problem

2010

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“…Kralchevsky [1] stated that there were many experimental indications that surfactant solution may dissolve or diffuse into glass substrate. It was been detected in surface-force measurements.…”

Section: Methodsmentioning

confidence: 99%

Surfactant effects on contact line alteration of a liquid drop in a capillary tube

Yulianti

Marwati

2018

J. Phys.: Conf. Ser.

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Abstract. In this paper, the effect of an insoluble surfactant on the moving contact line of an interface between two fluids filling a capillary tube is studied. The governing equations are the incompressible Navier-Stokes equations with the couple of Eulerian fluid variables and Lagrangian interfacial markers. In our model, capillary force plays a role in the fluids motion. Here, we propose that besides lowering the interfacial tension which affects the capillary force, the surfactant also decreases the surface tension between fluids and a solid surface. That condition is applied to the unbalanced Young condition at the contact line. The front-tracking method is used to solve numerically the free boundary motion of the interface. Results show that the surfactant has a significant effect on the motion of the contact line.

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“…Several studies have examined oil detachment from solid surfaces in the past. The solid substrates considered included silica [10], gold [11], or glass [12,13]. For a stainless steel surface, the results are different whether the surfactant used is ionic or nonionic.…”

Section: Reference Solution (Rs) Degreasing Performance Evaluationmentioning

confidence: 99%

Acidic surfactant solutions for tributylphosphate removal in nuclear fuel reprocessing plants: A formulation study

Causse

Faure

2009

Chemical Engineering Journal

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Detachment of Oil Drops from Solid Surfaces in Surfactant Solutions: Molecular Mechanisms at a Moving Contact Line

Cited by 52 publications

References 51 publications

Continuum models for the contact line problem

Continuum models for the contact line problem

Surfactant effects on contact line alteration of a liquid drop in a capillary tube

Acidic surfactant solutions for tributylphosphate removal in nuclear fuel reprocessing plants: A formulation study

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