(281c) Interfacial Rheology and Structure of Straight-Chain and Branched Fatty Alcohol Mixtures

Langmuir monolayers of mixtures of straight-chain and branched molecules of hexadecanol and eicosanol were studied using surface pressure-area isotherms, Brewster angle microscopy, and interfacial rheology measurements. For hexadecanol mixtures below 30% branched molecules, the isotherms show a lateral shift to a decreasing area proportional to the fraction of straight chains. Above 30% branched fraction, the isotherms are no longer identical in shape. The surface viscosities of both straight and mixed monolayers exhibit a maximum in the condensed untilted LS phase at P = 20 mN/m. Adding branched chains results in a non-monotonic increase in surface viscosity, with the maximum near 12% branched hexadecanol. Visualization of these immiscible monolayers using Brewster angle microscopy in the liquid condensed phase show the formation of discrete domains that initially increase in number density, then decrease with increasing surface pressure. Eicosanol mixtures exhibit different rheological and structural behavior from hexadecanol mixtures. The addition of branched chains results in a lateral shift to increasing area, proportional to the fraction and projected area of both straight and branched chains. A phase transition is seen for all mixtures, including pure straight chains, at P =15 mN/m up to 50% branched chains. A second transition is seen at P = 25 mN/m when the isotherms cross over. Above this transition, the isotherms shift in the reverse direction with increasing branched fraction. The surface viscosities of both straight and mixed monolayers show a maximum in the L₂' phase near P = 5 mN/m. The surface viscosity is constant for low branched fraction, and decays beyond 15% branched chains.