@article{talwar_scanu_raghavan_khan_2008, title={Influence of binary surfactant mixtures on the rheology of associative polymer solutions}, volume={24}, ISSN={["0743-7463"]}, DOI={10.1021/la801030n}, abstractNote={Hydrophobically modified alkali-soluble emulsion polymers (HASE) are a class of comblike associative polymers that can impart high viscosities to aqueous solutions. The rheology of HASE solutions can be tuned by the addition of surfactants, such as nonylphenol ethoxylates (NP e), where e is the length of the hydrophilic (ethoxylate) chain. While previous studies have considered individual surfactants, our focus here is on binary surfactant mixtures. We find that equimolar NP4-NP12 mixtures significantly enhance the zero-shear viscosities of HASE solutions as compared to equivalent amounts of NP8, especially at high overall surfactant concentrations. Dynamic rheological measurements suggest that the higher viscosities are due to increases in the lifetime of hydrophobic junctions in the polymer-surfactant network. In contrast to the above results, equimolar NP4-NP8 mixtures are rheologically identical to equivalent solutions of NP6. The differences between the two sets of mixtures are further correlated with cloud point measurements and thereby with the overall hydrophilic-lipophilic balance (HLB) of the surfactant system.}, number={15}, journal={LANGMUIR}, author={Talwar, Sachin and Scanu, Lauriane and Raghavan, Srinivasa R. and Khan, Saad A.}, year={2008}, month={Aug}, pages={7797–7802} }
 @article{chennamsetty_bock_scanu_siperstein_gubbins_2005, title={Cosurfactant and cosolvent effects on surfactant self-assembly in supercritical carbon dioxide}, volume={122}, ISSN={["1089-7690"]}, DOI={10.1063/1.1855291}, abstractNote={The impact of alcohol additives on the self-assembly of surfactants in supercritical carbon dioxide is investigated using lattice Monte Carlo simulations. We observe that all studied (model) alcohols reduce the critical micelle concentration. The reduction is stronger the longer the hydrocarbon chain of the alcohol, and the higher the alcohol concentration. Short-chain alcohols are found to concentrate in the surfactant layer of the aggregates, replacing surfactant molecules and leading to a strong decrease of the aggregation number and a large increase of the number of aggregates. On the other hand, only a small number of alcohol molecules with longer chain length are found in the aggregates, leading to a slight increase in the aggregation number. However, structural properties such as size and density profiles of aggregates at the same aggregation number are not influenced markedly. Consequently, short-chain alcohols act as cosurfactants, directly influencing the properties of the aggregates, while alcohols with longer hydrocarbon chains work as cosolvents, altering the properties of the solvent. However, the transition between both extremes is gradual.}, number={9}, journal={JOURNAL OF CHEMICAL PHYSICS}, author={Chennamsetty, N and Bock, H and Scanu, LF and Siperstein, FR and Gubbins, KE}, year={2005}, month={Mar} }
 @article{scanu_gubbins_hall_2004, title={Lattice Monte Carlo simulations of phase separation and micellization in supercritical CO2/surfactant systems: Effect of CO2 density}, volume={20}, ISSN={["0743-7463"]}, DOI={10.1021/la0347760}, abstractNote={Lattice Monte Carlo simulations are used to study the effect of nonionic surfactant concentration and CO2 density on the micellization and phase equilibria of supercritical CO2/surfactant systems. The interaction parameter for carbon dioxide is obtained by matching the critical temperature of the model fluid with the experimental critical temperature. Various properties such as the critical micelle concentration and the size, shape, and structure ofmicelles are calculated, and the phase diagram in the surfactant concentration-CO2 density space is constructed. On increasing the CO2 density, we find an increase in the critical micelle concentration and a decrease in the micellar size; this is consistent with existing experimental results. The variation of the micellar shape and structure with CO2 density shows that the micelles are spherical and that the extension of the micellar core increases with increasing micellar size, while the extension of the micellar corona increases with increasing CO2 density. The predicted phase diagram is in qualitative agreement with experimental phase diagrams for nonionic surfactants in carbon dioxide.}, number={2}, journal={LANGMUIR}, author={Scanu, LF and Gubbins, KE and Hall, CK}, year={2004}, month={Jan}, pages={514–523} }
 @article{talwar_scanu_khan, title={Hydrophobic interactions in associative polymer/nonionic surfactant systems: Effects of surfactant architecture and system parameters}, volume={50}, number={6}, journal={Journal of Rheology (New York, N.Y.)}, author={Talwar, S. and Scanu, L. F. and Khan, S. A.}, pages={831–847} }