The main target of this study is to develop a theoretical method for determining small contents of
dodecanol in samples of sodium dodecyl sulfate (SDS) by a detailed analysis of surface-tension isotherms.
As a tool for our analysis, we employ the van der Waals model. Its application to data for alkanols and
anionic surfactants gives an excluded area per adsorbed molecule equal to the geometrical area of the
molecular cross section and adsorption energies consonant with Traube's rule. Because the dodecanol and
SDS have different excluded areas, we extended the van der Waals model for the case of a two-component
adsorption layer, with account for the counterion binding in the Stern layer. General expressions for the
surface free energy, two-dimensional equation of state, surface chemical potentials, adsorption isotherms,
and surface dilatational elasticity are derived. The experimental surface-tension isotherms are fitted by
varying only one adjustable parameter. The model was successfully tested against data for solutions of
SDS with a known content of dodecanol. Knowing the parameters of the model, we computed various
properties of the surfactant adsorption layer. The results show that the presence of a small amount of
dodecanol leads to a considerable increase of the total adsorption and surface elasticity. Even a relatively
small (0.2 mol %) fraction of dodecanol in SDS may lead to a predominant content (up to 86 mol %) of
dodecanol in the mixed adsorption layer. We applied the model for determining unknown contents of
dodecanol in SDS samples at different stages of purification. The addition of NaCl may lead to a significant
reduction in the mole fraction of dodecanol in the adsorption layer. The developed theoretical model and
computational procedure are also appropriate for a quantitative analysis and computer modeling of the
adsorption from other mixed ionic−nonionic surfactant solutions, at both air−water and oil−water interfaces.
To interpret quantitatively experimental data for the growth of rodlike anionic surfactant micelles in
the presence of Al3+ ions, we undertook experimental and theoretical investigations. We determined the
micelle size, shape, and interactions by light scattering and examined the binding of Al3+ ions to the
micelles by ultrafiltration. Independent static and dynamic light scattering measurements indicated that
the effect of the micelle−micelle interactions in these solutions can be neglected. The major factor promoting
the micelle growth turns out to be the binding of Al3+ ions to the micelle surfaces, which considerably
affects the standard chemical potential of the aggregated surfactant molecules and can alter the micellization
constant by orders of magnitude. The latter effect was described theoretically. The model of micelle
growth, extended in this way, compared well with the experimental data. The model provides a quantitative
description of the micelle size and charge as functions of the surfactant and electrolyte concentrations.
It turns out that the rodlike micelles have a lower surface charge than the spherical ones, and this makes
their growth energetically favorable. A practical application may follow from the markedly greater
solubilization efficiency of the studied rodlike micelles compared to the spherical ones.
scite is a Brooklyn-based organization that helps researchers better discover and understand research articles through Smart Citations–citations that display the context of the citation and describe whether the article provides supporting or contrasting evidence. scite is used by students and researchers from around the world and is funded in part by the National Science Foundation and the National Institute on Drug Abuse of the National Institutes of Health.