Depth-Resolved Vibrational SFG/DFG Spectroscopy of the Anisotropic Water Structure at Charged Interfaces

Abstract: The molecular structure of water at charged aqueous interfaces is shaped by interfacial electric fields, which can induce significant anisotropy in the molecular orientations that extends over nanometer-scale distances. Despite great relevance, very little is known about the details of this depth-dependent anisotropic water structure, mainly due to the lack of appropriate experimental techniques. Here, we present a time-domain spectrometer specifically developed to acquire depth-resolved nonlinear vibrational spectra at aqueous interfaces. The approach is based on combining phase-resolved vibrational sum- and difference-frequency spectra and enables the extraction of depth information on the nanometer scale. The analysis of the acquired resonant spectral line shapes meanwhile yields insight into local hydrogen-bond structures and anisotropic molecular orientations across the interfacial region. In measurements with insoluble charged surfactants, we demonstrate that the obtained data allows for a full reconstruction of the nonlinear vibrational responses as function of depth. The results show the presence of two pronounced regions within the interfacial anisotropy with largely deviating degrees of preferential molecular orientations. A spectral analysis of the depth-dependent vibrational responses furthermore reveals that the natural local hydrogen-bond structure of bulk water remains intact throughout the interfacial region, including water in the direct proximity of the surface charges. These findings significantly refine our understanding of the anisotropic water structure at the interface to charged surfactants and showcase the large potential of our depth-resolved spectroscopic technique.