C-60-propylamine adduct monolayers at the gas/water interface: A Brewster angle microscopy and x-ray scattering study

Brewster angle microscopy (BAM), x-ray specular reflectivity and grazing-incidence x-ray diffraction (GID) studies of C-60-propylamine adduct monolayers at the gas/water interface as a function of molecular area are reported. At large molecular areas (A>similar to 150 Angstrom(2)/molecule), BAM images reveal macroscopic heterogeneity in the film, consisting of the coexistence between regions covered with uniform solidlike monolayer and bare water surface. After compression to a limiting molecular area of 150 Angstrom(2)/molecule, the film is observed to be homogeneous, with the uniform monolayer covering the entire available surface. Both the x-ray reflectivity results and the GID patterns are consistent with the formation of a uniform monolayer at A similar to 150 Angstrom(2)/molecule, while the little dependence that the GID patterns have on the molecular area for A>similar to 150 Angstrom(2)/molecule is consistent with the heterogeneity in the film. Upon further compression to higher densities (A<similar to 120 Angstrom(2)/molecule), the x-ray-reflectivity results suggest the formation of a partial layer either at the molecule/gas interface or at the molecule/water interface. In this high density regime, the shift in the observed GID pattern with molecular area is much smaller than would be expected if the film were to remain a homogeneous monolayer, also consistent with the formation of an inhomogeneous partial layer. The analysis of the broad GID pattern observed from a uniform monolayer in terms of a model 2D radial distribution function, implies a short range positional correlation, extending to only a few molecular distances. The average nearest neighbor distance (d similar to 13 Angstrom), extracted from the GID analysis, is consistent with the limiting molecular area (A similar to 150 Angstrom(2)/molecule) assuming local hexagonal packing. These results together with the sharp facets observed in the BAM images demonstrate that the monolayer when uniform is a two-dimensional amorphous solid. (C) 1997 American institute of Physics.