# Transition in a numerical model of contact line dynamics and forced   dewetting

**Authors:** S. Afkhami, J. Buongiorno, A. Guion, S. Popinet, Y. Saade, R., Scardovelli, S. Zaleski

arXiv: 1703.07038 · 2018-10-30

## TL;DR

This paper models contact line dynamics and forced dewetting transitions using a numerical approach that aligns with Cox's theory, revealing how contact angle and viscosity influence the critical capillary number.

## Contribution

It introduces a numerical method with a discretized contact angle that accurately captures contact line behavior and generalizes the Landau-Levich-Derjaguin transition prediction for various angles and viscosity ratios.

## Key findings

- Cox's theory applies to the numerical model with a gauge function.
- Agreement between numerics and theory depends on contact angle and viscosity ratio.
- The critical capillary number is generalized for large contact angles and arbitrary viscosity ratios.

## Abstract

We investigate the transition to a Landau-Levich-Derjaguin film in forced dewetting using a quadtree adaptive solution to the Navier-Stokes equations with surface tension. We use a discretization of the capillary forces near the receding contact line that yields an equilibrium for a specified contact angle $\theta_\Delta$ called the numerical contact angle. Despite the well-known contact line singularity, dynamic simulations can proceed without any explicit additional numerical procedure. We investigate angles from $15^\circ$ to $110^\circ$ and capillary numbers from $0.00085$ to $0.2$ where the mesh size $\Delta$ is varied in the range of $0.0035$ to $0.06$ of the capillary length $l_c$. To interpret the results, we use Cox's theory which involves a microscopic distance $r_m$ and a microscopic angle $\theta_e$. In the numerical case, the equivalent of $\theta_e$ is the angle $\theta_\Delta$ and we find that Cox's theory also applies. We introduce the scaling factor or gauge function $\phi$ so that $r_m = \Delta/\phi$ and estimate this gauge function by comparing our numerics to Cox's theory. The comparison provides a direct assessment of the agreement of the numerics with Cox's theory and reveals a critical feature of the numerical treatment of contact line dynamics: agreement is poor at small angles while it is better at large angles. This scaling factor is shown to depend only on $\theta_\Delta$ and the viscosity ratio $q$. In the case of small $\theta_e$, we use the prediction by Eggers [Phys. Rev. Lett., vol. 93, pp 094502, 2004] of the critical capillary number for the Landau-Levich-Derjaguin forced dewetting transition. We generalize this prediction to large $\theta_e$ and arbitrary $q$ and express the critical capillary number as a function of $\theta_e$ and $r_m$. An analogy can be drawn between $r_m$ and the numerical slip length.

## Full text

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## Figures

33 figures with captions in the complete paper: https://tomesphere.com/paper/1703.07038/full.md

## References

61 references — full list in the complete paper: https://tomesphere.com/paper/1703.07038/full.md

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Source: https://tomesphere.com/paper/1703.07038