Your search keyword '"Peter J. Dowding"' showing total 2 results

1. Are Hydrotropes Distinct from Surfactants?

Author

Marios Hopkins Hatzopoulos, Julian Eastoe, Peter J. Dowding, Sarah E. Rogers, Richard Heenan, and Robert Dyer

Subjects

*SURFACE active agents, *SODIUM compounds, *TRANSITION temperature, *CLUSTERING of particles, *SMALL-angle scattering, *NEUTRON scattering, *SURFACE tension

Abstract

The physicochemical properties of a homologous series of sodium p-n-alkylbenzoates have been investigated. The objective was to determine whether there is a clear transition point from hydrotropic to surfactant-like behavior with increasing alkyl chain length n, so as to shed clear light on the aggregation mechanism of so-called “hydrotropes”. Electrical conductivity measurements were used for a first estimation of the critical aggregation concentrations (cac). As for classical surfactants, log(cac) depends on alkyl chain length n, but two branches of behavior were observed: one having a gradient typical of long chain fatty acid salts and the other with a more shallow dependence. Surface tension (γ) measurements of high purity aqueous solutions were used to generate limiting headgroup areas Acac, which were in the range (40–50 Å2) being consistent with monolayer formation. Small-angle neutron scattering conclusively shows that the lower chain length homologues (classed as hydrotropes) exhibit sharp transitions in aggregation as a function of bulk concentration, typical of regular surfactants. As such, there is little to suggest from this study that hydrotropes differ in association behavior from regular surfactants. [ABSTRACT FROM AUTHOR]

Published

2011

2. Formation of Surfactant-Stabilized Silica Organosols.

Author

Rico F. Tabor, Julian Eastoe, Peter J. Dowding, Isabelle Grillo, Richard K. Heenan, and Martin Hollamby

Subjects

*SILICON compounds, *SURFACE active agents, *ORGANIC solvents, *NANOPARTICLES, *ZETA potential, *LIGHT scattering

Abstract

Organosols comprising silica nanoparticles, stabilized by adsorbed surfactant layers in low dielectric organic solvents were formulated, and their properties studied. A range of different methods for organosol formation starting from aqueous sols were evaluated and compared, in order to determine the most reliable and reproducible approach. To understand the influence of surfactant type and solvent on stability, samples were prepared with a range of surfactants and in different solvents and solvent blends. Structural properties and interparticle interactions were probed using dynamic light scattering (DLS), zeta potentials were determined, and the surfactant layers were investigated with contrast-variation SANS. SANS data suggest that for systems stabilized by ionic surfactants, the nanoparticles are in equilibrium with a population of reverse micelles, but this is apparently not the case for those stabilized by nonionic surfactants. Low zeta potentials show evidence of a small amount of surface charging in these nonaqueous systems, although it is unlikely to have any significant effect on their overall stability. [ABSTRACT FROM AUTHOR]

Published

2008