What Is So Special about Aerosol-OT? 2. Microemulsion Systems

Abstract: The aim was to identify why Aerosol-OT is such an efficient surfactant for forming microemulsions, and in pursuit of this, 11 Aerosol-OT-related compounds have been investigated. These surfactants were from two separate homologous series, with either linear or branched hydrocarbon tails. Hence, it was possible to examine the effect of chain structure on packing in curved interfacial films at oil-water interfaces. With the linear dichain compounds, water-in-oil microemulsion phases could be formed only in the p… Show more

“…This behaviour appears to gradually change with increasing alkanoate tail length. The AOT microemulsions shift stability region with increasing alkanoate chain length to lower temperatures and closer to the temperature range of stability for normal (hydrotrope-free) AOT microemulsions [19]. The longer the tail length the greater the 'alkyl' character of the additive and a stronger positive interaction between the additive and AOT tails is expected.…”

“…Because hydrotropes do not partition strongly into oil (they are only weakly hydrophobic), at low water content the effective hydrotrope concentration in the water pools is high, and hence they might be expected to adsorb strongly at the interface. For a fixed mole fraction x of hydrotrope in the total microemulsion, increasing the water content w decreases the additive concentration in the water droplets, and eventually the micellar geometry change to spherical, as found for the native AOT (hydrotrope-free) systems [19]. However, the extent of axial elongation did not appear to directly correlate to additive architecture, with some less hydrophobic additives inducing longer cylinders as compared to the more hydrophobic homologues and analogues.…”

“…Å and 32.9 Å for w = 10 and w = 20 respectively [19]. The presence of the additives causes a noticeable decrease in the mean radii of the microemulsions for any w value, at the same time the polydispersity increases with water content.…”

“…Reverse AOT/n-heptane/D2O microemulsions are known to be spherical with radius increasing proportionally with water content w [19]. In a previous study alkylhydrotropes induced a varying degree of axial elongation with rods and ellipsoids observed at w values where the corresponding concentration of the additive was above or in close proximity of the corresponding bulk critical aggregation concentration (cac or critical micelle concentration cmc), and below which the microemulsions became spherical [18].…”

“…Linear dependences of fitted radii with w for spherical microemulsions. The slope and intercept of the radii of the equations shown in Table 5 The Porod method for determining radii and head-group areas considers the scattering intensity I(Q) reporting from local interface at high Q values [19].…”

Effects of small ionic amphiphilic additives on reverse microemulsion morphology

“…This behaviour appears to gradually change with increasing alkanoate tail length. The AOT microemulsions shift stability region with increasing alkanoate chain length to lower temperatures and closer to the temperature range of stability for normal (hydrotrope-free) AOT microemulsions [19]. The longer the tail length the greater the 'alkyl' character of the additive and a stronger positive interaction between the additive and AOT tails is expected.…”

“…Because hydrotropes do not partition strongly into oil (they are only weakly hydrophobic), at low water content the effective hydrotrope concentration in the water pools is high, and hence they might be expected to adsorb strongly at the interface. For a fixed mole fraction x of hydrotrope in the total microemulsion, increasing the water content w decreases the additive concentration in the water droplets, and eventually the micellar geometry change to spherical, as found for the native AOT (hydrotrope-free) systems [19]. However, the extent of axial elongation did not appear to directly correlate to additive architecture, with some less hydrophobic additives inducing longer cylinders as compared to the more hydrophobic homologues and analogues.…”

“…Å and 32.9 Å for w = 10 and w = 20 respectively [19]. The presence of the additives causes a noticeable decrease in the mean radii of the microemulsions for any w value, at the same time the polydispersity increases with water content.…”

“…Reverse AOT/n-heptane/D2O microemulsions are known to be spherical with radius increasing proportionally with water content w [19]. In a previous study alkylhydrotropes induced a varying degree of axial elongation with rods and ellipsoids observed at w values where the corresponding concentration of the additive was above or in close proximity of the corresponding bulk critical aggregation concentration (cac or critical micelle concentration cmc), and below which the microemulsions became spherical [18].…”

“…Linear dependences of fitted radii with w for spherical microemulsions. The slope and intercept of the radii of the equations shown in Table 5 The Porod method for determining radii and head-group areas considers the scattering intensity I(Q) reporting from local interface at high Q values [19].…”

Effects of small ionic amphiphilic additives on reverse microemulsion morphology

Hydrogen Bonding Barrier‐Crossing Dynamics at Biomimicking Surfaces

Ionic Liquids Modify the AOT Interfacial Curvature and Self‐Assembly