Modeling of dynamic wetting far from equilibrium

Carlson, Andreas; Do-Quang, Minh; Amberg, Gustav

doi:10.1063/1.3275853

Cited by 90 publications

(109 citation statements)

References 12 publications

(24 reference statements)

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“…A non-monotonicity in µ f is observed for pure water for the SiO 2 and silane coating, the same dependency was reported in [14] when comparing with similar experiments [2]. We can at the present time not explain this non-monotonicity for pure water.…”

supporting

confidence: 35%

“…If accounting for the effects of convection of the concentration, that would equal the flux due to gradients of the chemical potential, the Cahn-Hilliard equation is recovered, which along with the Navier Stokes equations forms a theoretical basis for modeling of wetting [14] with a no-slip on the wall.…”

mentioning

confidence: 99%

“…To obtain the experimentally observed spreading behavior, an additional dissipation at the contact line was necessary through a non-zero µ f [14]. µ f was determined by obtaining a direct agreement between simulations and experiments, enabling a direct measurement of µ f even in the presence of other contributions such as viscosity and inertia [15].…”

mentioning

confidence: 99%

“…By integrating experiments and axi-symmetric simulations based on the Cahn-Hilliard Navier Stokes equations [14,15] we estimate values for the friction factor (µ f ) that appears in the free energy formulation. Theoretically, the friction factor generates a local dissipation at the contact line through its boundary condition.…”

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confidence: 99%

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Universality in dynamic wetting dominated by contact-line friction

2012

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We report experiments on the rapid contact line motion present in the early stages of capillary driven spreading of drops on dry solid substrates. The spreading data fails to follow a conventional viscous or inertial scaling. By integrating experiments and simulations, we quantify a contact line friction (µ f ), which is seen to limit the speed of the rapid dynamic wetting. A scaling based on this contact line friction is shown to yield a universal curve for the evolution of the contact line radius as a function of time, for a range of fluid viscosities, drop sizes and surface wettabilities.

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confidence: 35%

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confidence: 99%

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confidence: 99%

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confidence: 99%

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Universality in dynamic wetting dominated by contact-line friction

2012

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“…Qian et al 15 included such relaxation in their computation of the Couette flow but did not examine its effect. The simulation of Carlson et al 16 indicated that wall relaxation tends to inhibit the motion of the contact line and reduce the speed of drop spreading. But the mechanism for this is unclear.…”

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confidence: 99%

Wall energy relaxation in the Cahn–Hilliard model for moving contact lines

2011

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The Cahn–Hilliard model uses diffusion between fluid components to regularize the stress singularity at a moving contact line. In addition, it represents the dynamics of the near-wall layer by the relaxation of a wall energy. The first part of the paper elucidates the role of the wall relaxation in a flowing system, with two main results. First, we show that wall energy relaxation produces a dynamic contact angle that deviates from the static one, and derive an analytical formula for the deviation. Second, we demonstrate that wall relaxation competes with Cahn–Hilliard diffusion in defining the apparent contact angle, the former tending to “rotate” the interface at the contact line while the latter to “bend” it in the bulk. Thus, varying the two in coordination may compensate each other to produce the same macroscopic solution that is insensitive to the microscopic dynamics of the contact line. The second part of the paper exploits this competition to develop a computational strategy for simulating realistic flows with microscopic slip length at a reduced cost. This consists in computing a moving contact line with a diffusion length larger than the real slip length, but using the wall relaxation to correct the solution to that corresponding to the small slip length. We derive an analytical criterion for the required amount of wall relaxation, and validate it by numerical results on dynamic wetting in capillary tubes and drop spreading.

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Numerical Simulation of Wetting Phenomena with a Phase‐Field Method Using OpenFOAM®

et al. 2015

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The phase-field method coupled with the Navier-Stokes equations is a rather new approach for scale-resolving numerical simulation of interfacial two-phase flows. The intention is to implement it as finite-volume method in the open source library for computational continuum mechanics OpenFOAM and make it freely available. An overview on the governing equations is given and the numerical method is shortly discussed. The focus is on application and validation of the code for some fundamental wetting phenomena, namely the capillary rise in a narrow channel and the spreading of a droplet on a flat surface, which is chemically homogeneous or regularly patterned. The numerical results on static meshes agree well with analytical solutions and experimental/numerical results from literature. Also, first 3D finite-volume simulations with adaptive mesh refinement near the interface are presented as a key element to achieve CPU-time efficient simulations.

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Modeling of dynamic wetting far from equilibrium

Cited by 90 publications

References 12 publications

Universality in dynamic wetting dominated by contact-line friction

Universality in dynamic wetting dominated by contact-line friction

Wall energy relaxation in the Cahn–Hilliard model for moving contact lines

Numerical Simulation of Wetting Phenomena with a Phase‐Field Method Using OpenFOAM®

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