The interfaces of neat water and aqueous solutions play a prominent role in many technological processes and in the environment. Examples of aqueous interfaces are ultrathin water films that cover most hydrophilic surfaces under ambient relative humidities, the liquid/solid interface which drives many electrochemical reactions, and the liquid/vapor interface, which governs the uptake and release of trace gases by the oceans and cloud droplets. In this article we review some of the recent experimental and theoretical advances in our knowledge of the properties of aqueous interfaces and discuss open questions and gaps in our understanding.
Vibrational sum-frequency spectroscopy (SFS) and total internal reflection Raman scattering (TIR Raman) have been used to study the adsorption of hexadecyltrimethylammonium bromide (CTAB) to hydrophilic silica. These two complementary techniques permit the determination of the adsorbed amount with a sensitivity of approximately 1% of the maximum surface coverage, changes in the average tilt of the adsorbed molecules, the presence of asymmetric aggregates in the adsorbed film, and the structure and orientation of the water molecules in the interfacial region. The TIR Raman spectra show a monotonic increase with CTAB concentration with no measurable changes in the relative intensities of the different polarization combinations probed, implying that no significant changes occur in the conformational order of the hydrocarbon chain. In the sum-frequency (SF) spectra, no detectable peaks from the surfactant headgroup and hydrophobic chain were observed at any surface coverage. Major changes are observed in the water bands of the SF spectra, as the originally negatively charged silica surface becomes positively charged with an increase in the adsorbed amount, inducing a change in the polar orientation of the water molecules near the surface. The detection limits for hydrocarbons chains in the SF spectra were estimated by comparison with the SF spectrum of a disordered octadecyltrichlorosilane monolayer. The simulations demonstrate that the asymmetry in the adsorbed CTAB layer at any concentration is less than 5% of a monolayer. The results obtained pose severe constraints on the possible structural models, in particular at concentrations below the critical micellar concentration where information is scarce. The formation of hemimicelles, monolayers and other asymmetric aggregates is ruled out, with centrosymmetric aggregates forming from early on in the adsorption process.
The OH stretching region of water molecules in the vicinity of nonionic surfactant monolayers has been investigated using vibrational sum frequency spectroscopy (VSFS) under the polarization combinations ssp, ppp, and sps. The surface sensitivity of the VSFS technique has allowed targeting the few water molecules present at the surface with a net orientation and, in particular, the hydration shell around alcohol, sugar, and poly(ethylene oxide) headgroups. Dramatic differences in the hydration shell of the uncharged headgroups were observed, both in comparison to each another and in comparison to the pure water surface. The water molecules around the rigid glucoside and maltoside sugar rings were found to form strong hydrogen bonds, similar to those observed in tetrahedrally coordinated water in ice. In the case of the poly(ethylene oxide) surfactant monolayer a significant ordering of both strongly and weakly hydrogen bonded water was observed. Moreover, a band common to all the surfactants studied, clearly detected at relatively high frequencies in the polarization combinations ppp and sps, was assigned to water species located in proximity to the surfactant hydrocarbon tail phase, with both hydrogen atoms free from hydrogen bonds. An orientational analysis provided additional information on the water species responsible for this band.
The charging of arachidic
acid Langmuir monolayers as a function
of subphase pH and monovalent ion concentration below 100 mM was investigated
using vibrational sum frequency spectroscopy. Molecular information
was obtained by targeting the vibrational modes of the carboxylic
acid headgroups, alkyl chains, and water molecules in the immediate
surface and diffuse double layers. The surface charge in the monolayer
was experimentally determined by monitoring the hydrated carboxylate
stretching modes. The charging behavior was found to be in excellent
agreement with that predicted by Gouy–Chapman theory using
a thermodynamic pK
a of 5.1 ± 0.2.
This resulted in an apparent pK
a of ∼10.8
when the only ions present in solution were those associated with
adjusting the pH. Water molecules with a preferred orientation in
the immediate surface region were found to primarily interact with
the uncharged carboxylic acid moiety, decreasing in number as the
monolayer further deprotonated. Contributions from water molecules
in the diffuse double layer, partly aligned by the exponentially decaying
surface electric field, closely followed the predictions of a recently
proposed theoretical framework that accounts for interference and
screening effects. Finally, the charging of the monolayer was experimentally
found to be independent of the identity of either the monovalent cation
(i.e., Li+, Na+, Rb+) or anion (i.e.,
F–, Cl–, I–)
at low salt concentrations.
ARTICLEmonolayer of dodecanol is used to explore the limitations and advantages of performing an orientational analysis of the terminal methyl in the CD region.
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