Observation of a Structural Gradient in the Middle, Bicontinuous Microemulsion, Phase of Winsor-III Systems
Hayes, D. G., S. V. Pingali, H. M. O'Neill, V. S. Urban, and Y. Ran.  2017.  Soft Matter, 14, 5270 5276.

We demonstrate here for the first time via small-angle neutron scattering (SANS) that the middle, bicontinuous microemulsion (BME), phase of Winsor-III systems undergoes gradual change of structure and composition in the vertical direction, contrary to the commonly held belief of uniform structure and composition. A vertical stage was deployed to enable precise alignment of the rectangular cell containing the WIII system with respect to the neutron beam, allowing for several different vertical positions to be analyzed. For the water/AOT/CK-2,13 (two-tailed alkyl ethoxylate containing a 1,3-dioxolane linkage)/heptane Winsor-III system, the quasi-periodic repeat distance (d) and correlation length (e), obtained from the Teubner-Strey model applied to the SANS data, decreased and the surface area per volume of the surfactant monolayer (via Porod analysis) increased in the downward direction, trends that reflect an increase of surfactant concentration, consistent with the ultralow interfacial tension that often occurs for the lower liquid-liquid interface of many WIII systems. The water/sodium dodecyl sulfate (SDS)/1-pentanol/dodecane system shared the same trend with regard to d as observed for AOT/CK-2,13. In contrast, for SDS/pentanol, e increased and the amphiphilicity factor (fa) decreased in the downward direction, trends consistent with a decrease of cosurfactant (pentanol) concentration in the downward direction. Non-uniformity in the vertical direction have implications in the transport of solutes between WIII phases during the extractive purification of proteins or removal of heavy metals and pollutants from wastewater, or the deposition of BMEs onto hydrophilic vs. hydrophobic surfaces as thin coatings.