The
influence of lithium chloride (LiCl) on the hydration structure
of anionic micelles of sodium dodecyl sulfate (SDS) in water was studied
using the contrast-variation small-angle neutron scattering (SANS)
technique. In the past, extensive computational studies have shown
that the distribution of invasive water plays a critical role in the
self-organization of SDS molecules and the stability of the assemblies.
However, in past scattering studies the degree of the hydration level
was not examined explicitly. Here, a series of contrast-variation
SANS data was analyzed to extract the intramicellar radial distributions
of invasive water and SDS molecules from the evolving spectral lineshapes
caused by the varying isotopic ratios of water. By addressing the
intramicellar inhomogeneous distributions of water and SDS molecules,
a detailed description of how the counterion association influences
the micellization behavior of SDS molecules is provided. The extension
of our method can be used to provide an in-depth insight into the
micellization phenomenon, which is commonly found in many soft matter
systems.
Self-assembly of amphiphilic polymers in water is of fundamental and practical importance. Significant amounts of free unimers and associated micellar aggregates often coexist over a wide range of phase regions. The thermodynamic and kinetic properties of the microphase separation are closely related to the relative population density of unimers and micelles. Although the scattering technique has been employed to identify the structure of micellar aggregates as well as their time-evolution, the determination of the population ratio of micelles to unimers remains a challenging problem due to their difference in scattering power. Here, using small-angle neutron scattering (SANS), we present a comprehensive structural study of amphiphilic n-dodecyl-PNIPAm polymers, which shows a bimodal size distribution in water. By adjusting the deuterium/hydrogen ratio of water, the intra-micellar polymer and water distributions are obtained from the SANS spectra. The micellar size and number density are further determined, and the population densities of micelles and unimers are calculated to quantitatively address the degree of micellization at different temperatures. Our method can be used to provide an in-depth insight into the solution properties of microphase separation, which are present in many amphiphilic systems.
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