Leveling of a model paint film with a yield stress

 The liquid was modeled as a binary mixture with one volatile component, solvent, and one nonvolatile component, resin. When the solvent had a different surface tension than the resin, solvent evaporation can lead to the creation of surface tension gradients which can potentially overcome the yield stress and dramatically affect the flow history.

Using the lubrication approximations to derive the flux of the liquid film parallel to the substrate, the researchers found that the presence of the yield stress causes several distinct flow regimes. The total flux of each of these regimes is summed, and using the continuity equation the scientists derive an evolution equation giving the height of the free surface as a function of the distance along the substrate and time.

Presence of a yield stress greatly affects the leveling behavior

The resulting equations were discretised and solved numerically using finite differences. High order derivative was treated implicitly, allowing for large time steps and reducing the computational requirements. It was found that the presence of a yield stress greatly affects the leveling behavior of the coating. Critical yield stresses exist that can cause maximal leveling of the coating film.

The study has been published in Journal of Coatings Technology and Research. Volume 17, Issue 4.

Image source: Pixabay.