Modeling dynamic surface tension on surfactant-enhanced polydimethylsiloxane (PDMS)

TL;DR

This study develops a new empirical model for dynamic surface tension that better predicts water wetting on surfactant-treated PDMS, revealing surfactant-specific effects on spreading and demonstrating model applicability across various surfactants.

Contribution

The paper introduces a novel empirical model for dynamic surface tension that outperforms existing models in describing wetting on surfactant-enhanced PDMS surfaces.

Findings

The new model fits experimental data better than existing models.

Siloxane ethoxylate surfactants promote faster water spreading on PDMS.

The model is applicable to a wide range of surfactants with different properties.

Abstract

Hypothesis: Surfactants are often added to aqueous solutions to induce spreading on otherwise unwettable hydrophobic surfaces. Alternatively, they can be introduced directly into solid hydrophobic materials-such as the soft elastomer, polydimethylsiloxane-to induce autonomous spreading without requiring additional surface or liquid modifications. Given the similarity between mechanisms of these two approaches, models that describe wetting by aqueous surfactant solutions should also characterize wetting on surfactant-solid systems. Experiments: Multiple surfactants of varying size and chemical composition were added to pre-polymerized PDMS samples. After cross-linking, water droplets were placed on the surfaces at set time points, and their contact angles were recorded to track the temporal evolution of the interfacial tension. Multiple nonlinear models were fitted to this data, their parameters analyzed, and each goodness of fit compared. Findings: An empirical model of dynamic surface tension was found to describe the wetting process better than the single established model found in the literature. The proposed model adapted better to the longer timescales induced by slow molecular diffusivity in PDMS. Siloxane ethoxylate surfactants induced faster and more complete wetting of PDMS by water than oxyoctylphenol ethoxylates did. The generalizability of this model for characterizing surfactants of a wide range of physiochemical properties was demonstrated.