Neutron reflectometry on superspreading and non-superspreading trisiloxane surfactants

TL;DR

This study uses neutron reflectivity to compare molecular layer compositions of superspreading and non-superspreading trisiloxane surfactants, revealing thermodynamic differences that explain their spreading behaviors.

Contribution

It introduces a novel neutron reflectivity analysis method to determine surfactant layer composition at the solid-liquid interface, elucidating molecular factors behind superspreading.

Findings

Superspreading surfactants form different interfacial layers than non-superspreading ones.

Thermodynamic explanations account for differences in spreading behavior.

The method accurately characterizes surfactant film composition at micrometer scales.

Abstract

Certain trisiloxane surfactants have the remarkable property of being able to superspread: Small volumes of water rapidly wet large areas of hydrophobic surfaces. The molecular properties of the surfactants which govern this technologically relevant effect are still under debate. To gain a deeper understanding, the surfactant behaviour during the spreading process needs to be studied at molecular length scales. Here, we present neutron reflectivity analyses of two trisiloxane surfactants of similar chemical structure, of which only one exhibits superspreading properties. We present an approach to determining the composition of the adsorbed surfactant layer in spread surfactant films at the solid-liquid interface, accounting for contributions from attenuated back-reflections of the neutron beam in films with thicknesses in the range of several tens to hundreds of micrometers. Differences between superspreading and non-superspreading surfactants with regard to their volume fraction profiles at the solid/liquid interface obtained in the self-consistent analysis of the reflectivity curves are in agreement with a simple explanation of the difference in spreading behaviour based on thermodynamics.