Quantification of Stern Layer Water Molecules, Total Potentials, and Energy Densities at Fused Silica:Water Interfaces for Adsorbed Alkali Chlorides, CTAB, PFOA, and PFAS.

We have employed amplitude- and phase-resolved second-harmonic generation spectroscopy to investigate ion-specific effects of monovalent cations at the fused silica:water interface maintained under acidic, neutral, and alkaline conditions. We find a negligible dependence of the total potential (as negative as -400 mV at pH 14), the second-order nonlinear susceptibility (as large as 1.5 × 10-21 m2 V-1 at pH 14), the number of Stern layer water molecules (1 × 1015 cm-2 at pH 5.8), and the energy associated with water alignment upon going from neutral to high pH (ca. -24 kJ mol-1 to -48 kJ mol-1 at pH 13 and 14, close to the cohesive energy of liquid water but smaller than that of ice) on chlorides of the alkali series (M+ = Li+, Na+, K+, Rb+, and Cs+). Attempts are presented to provide estimates for the molecular hyperpolarizability of the cations and anions in the Stern layer at high pH, which arrive at ca. 20-fold larger values for αtotal ions(2) = αM+(2) + αOH-(2) + αCl-(2) when compared to water's molecular hyperpolarizability estimate from theory and point to a sizable contribution of deprotonated silanol groups at high pH. In contrast to the alkali series, a pronounced dependence of the total potential and the second-order nonlinear susceptibility on monovalent cationic (cetrimonium bromide, CTAB) and anionic (perfluorooctanoic and perfluorooctanesulfonic acid, PFOA and PFOS) surfactants was quantifiable. Our findings are consistent with a low surface coverage of the alkali cations and a high surface coverage of the surfactants. Moreover, they underscore the important contribution of Stern layer water molecules to the total potential and second-order nonlinear susceptibility. Finally, they demonstrate the applicability of heterodyne-detected second-harmonic generation spectroscopy for identifying perfluorinated acids at mineral:water interfaces.

In Situ Ni2+ Stain for Liposome Imaging by Liquid-Cell Transmission Electron Microscopy.

Solvated soft matter, both biological and synthetic, can now be imaged in liquids using liquid-cell transmission electron microscopy (LCTEM). However, such systems are usually composed solely of organic molecules (low Z elements) producing low contrast in TEM, especially within thick liquid films. We aimed to visualize liposomes by LCTEM rather than requiring cryogenic TEM (cryoTEM). This is achieved here by imaging in the presence of aqueous metal salt solutions. The increase in scattering cross-section by the cation gives a staining effect that develops in situ, which could be captured by real space TEM and verified by in situ energy dispersive x-ray spectroscopy (EDS). We identified beam-induced staining as a time-dependent process that enhances contrast to otherwise low contrast materials. We describe the development of this imaging method and identify conditions leading to exceptionally low electron doses for morphology visualization of unilamellar vesicles before beam-induced damage propagates.

Direct Measurement of Charge Reversal on Lipid Bilayers Using Heterodyne-Detected Second Harmonic Generation Spectroscopy.

We report the detection of charge reversal induced by the adsorption of an aqueous cationic polyelectrolyte, poly(allylamine hydrochloride) (PAH), to supported lipid bilayers (SLBs) used as idealized model biological membranes. Through the use of an α-quartz reference crystal, we quantify the total interfacial potential at the interface in absolute units using heterodyne-detected second harmonic generation (HD-SHG) as an optical voltmeter. This quantification is made possible by isolating the phase-shifted potential-dependent third-order susceptibility from other contributions to the total SHG response. We detect the sign and magnitude of the surface potential and the point of charge reversal at buried interfaces without prior information or complementary data. Isolation of the second-order susceptibility contribution from the overall SHG response allows us to directly characterize the Stern and diffuse layers over single-component SLBs. We apply the method to SLBs formed from three different zwitterionic lipids having different gel-to-fluid phase transition temperatures (Tm's). We determine whether the surface potential changes with the physical phase state (gel, transitioning, or fluid) of the SLB. Furthermore, we incorporate 20% of negatively charged lipids to the zwitterionic SLB to investigate how the surface potential and the second-order nonlinear susceptibility χ(2) change with surface charge.

Beyond the Gouy-Chapman Model with Heterodyne-Detected Second Harmonic Generation.

We report ionic strength-dependent phase shifts in second harmonic generation (SHG) signals from charged interfaces that verify a recent model in which dispersion between the fundamental and second harmonic beams modulates observed signal intensities. We show how phase information can be used to unambiguously separate the χ(2) and interfacial potential-dependent χ(3) terms that contribute to the total signal and provide a path to test primitive ion models and mean field theories for the electrical double layer with experiments to which theory must conform. Finally, we demonstrate the new method on supported lipid bilayers and comment on the ability of our new instrument to identify hyper-Rayleigh scattering contributions to common homodyne SHG measurements in reflection geometries.

Bacterial Model Membranes Deform ( resp. Persist) upon Ni2+ Binding to Inner Core ( resp. O-Antigen) of Lipopolysaccharides.

The surface charge densities, apparent equilibrium binding constants, and free energies of binding of nickel ions to supported and suspended lipid membranes prepared from POPC and two types of lipopolysaccharide (LPS) are reported. Second- and third-order nonlinear optical mixing shows that rough LPS (rLPS)-incorporated bilayers carry the highest charge density and provide the most binding sites for nickel ions while LPS-free bilayers exhibit the lowest charge density and fewest binding sites. Ni2+ binding is almost fully reversible at low concentrations but less so at higher Ni2+ concentrations. Ni2+ adsorption isotherms exhibit hysteresis loops. The role of interfacial depth on the observed second harmonic generation (SHG) responses is discussed in the context of complementary dynamic light scattering, X-ray spectroscopy, and cryogenic transmission electron microscopy experiments. The latter reveal considerable Ni2+-induced structural deformations to the bacterial membrane models containing the short, O-antigen-free rLPS, consistent with complex formation on the vesicle surfaces that involve Ni2+ ions and carboxylate groups in the inner core of rLPS. In contrast, Ni2+ ion complexation to the charged groups (phosphates and carboxylate) of the considerably longer O-antigen units in sLPS appears to protect the phospholipid backbone against metal binding and thus preserve the vesicle structure.