Probing the Mineral–Water Interface with Nonlinear Optical Spectroscopy

Backus, Ellen H. G.; Schaefer, John P.; Bonn, Mischa

doi:10.1002/anie.202003085

“…The spectrum of χ (3) is similar to that of bulk water, 19 which is consistent with the diffuse layer exhibiting bulk-like hydrogen bonding with a small amount of net alignment due to the presence of the static electric field. This static electric field emanating in the z-direction (along the surface normal) can be related to the electrostatic potential 46 Although the potential at the silica surface is often invoked in the χ (3) technique, [47][48][49] according to the Gouy-Chapman-Stern-Grahame model of the electric double layer, the potential which aligns water in the diffuse layer is that outside of the outer Helmholtz plane (OHP), rather than the surface. This diffuse layer potential, which we argue is the potential that contributes to the χ (3) term, is often approximated as the zeta potential (ζ), which is experimentally determined based on the electrokinetic or electrophoretic properties of a system.…”

Section: Resultsmentioning

confidence: 99%

Role of Ions on the Surface-Bound Water Structure at the Silica/Water Interface: Identifying the Spectral Signature of Stability

Rehl

¹

,

Gibbs

²

2021

J. Phys. Chem. Lett.

View full text Add to dashboard Cite

We explore the influence of salt addition on the structure of water interacting closely with a charged silica surface. Isolating these surface effects is challenging, even with surface-specific techniques like sum frequency generation (SFG), because of the presence of aligned water nanometers to microns away from the charged silica. Here we combine zeta potential and SFG intensity measurements with the maximum entropy method and reported heterodyne second harmonic and sum frequency generation results to deconvolute from the total signal intensity the SFG spectral contributions of the waters adjacent to the surface. Deconvolution reveals that at very low ionic strength the surface water structure is similar to that of a neutral silica surface near the point of zero charge with waters oriented in opposite directions. This result suggests the known metastability of silica near the PZC and the stability of silica in low ionic strength solutions may originate from the same source, these oppositely oriented surface-bound waters. Orientation changes are induced upon adding salt, which lead to a decrease in the total amount of aligned water at the surface. File list (2) download file view on ChemRxiv Rehl Manuscript.pdf (1.99 MiB) download file view on ChemRxiv Rehl Supporting Information.pdf (2.26 MiB)

show abstract

“…The systems described above have been chosen as representative examples to discuss water at charged interfaces and because they are systems that the authors have extensively investigated, but by no means are the only possible examples of charged interfaces 6,17,[29][30][31][32][33][34][35] . All the systems considered in this Review feature a charged interface in contact with an aqueous solution containing ions.…”

mentioning

confidence: 99%

Water at charged interfaces

Gonella

¹

,

Backus

²

,

Nagata

³

et al. 2021

Self Cite

View full text Add to dashboard Cite

The ubiquity of aqueous solutions in contact with charged surfaces and the realization that the molecular-level details of water-surface interactions often determine interfacial functions and properties relevant in many natural processes have led to intensive research. Even so, many open questions remain regarding the molecular picture of the interfacial organization and preferential alignment of water molecules, as well as the structure of water molecules and ion distributions at different charged interfaces. While water, solutes and charge are present in each of these systems, the substrate can range from living tissues to metals. This diversity in substrates has led to different communities considering each of these types of aqueous interface. In this Review, by considering water in contact with metals, oxides and biomembranes, we show the essential similarity of these disparate systems. While in each case the classical mean-field theories can explain many macroscopic and mesoscopic observations, it soon becomes apparent that such theories fail to explain phenomena for which molecular properties are relevant, such as interfacial chemical conversion. We highlight the current knowledge and limitations in our understanding and end with a view towards future opportunities in the field.

show abstract

“…is similar to that of bulk water, 19 which is consistent with the diffuse layer exhibiting bulk-like hydrogen bonding with a small amount of net alignment due to the presence of the static electric field. This static electric field emanating in the z-direction (along the surface normal) can be related to the electrostatic potential 46 Although the potential at the silica surface is often invoked in the χ (3) technique, [47][48][49] according to the Gouy-Chapman-Stern-Grahame model of the electric double layer, the potential which aligns water in the diffuse layer is that outside of the outer Helmholtz plane (OHP), rather than the surface. This diffuse layer potential, which we argue is the potential that contributes to the χ (3) term, is often approximated as the zeta potential (ζ), which is experimentally determined based on the electrokinetic or electrophoretic properties of a system.…”

Section: Resultsmentioning

confidence: 99%

The Role of Ions on the Surface-Bound Water Structure at the Silica/Water Interface: Identifying the Spectral Signature of Stability

Rehl¹,

Gibbs²

2020

Preprint

1

0

View full text Add to dashboard Cite

We explore the influence of salt addition on the structure of water interacting closely with a charged silica surface. Isolating these surface effects is challenging, even with surface-specific techniques like sum frequency generation (SFG), because of the presence of aligned water nanometers to microns away from the charged silica. Here we combine zeta potential and SFG intensity measurements with the maximum entropy method and reported heterodyne second harmonic and sum frequency generation results to deconvolute from the total signal intensity the SFG spectral contributions of the waters adjacent to the surface. Deconvolution reveals that at very low ionic strength the surface water structure is similar to that of a neutral silica surface near the point of zero charge with waters oriented in opposite directions. This result suggests the known metastability of silica near the PZC and the stability of silica in low ionic strength solutions may originate from the same source, these oppositely oriented surface-bound waters. Orientation changes are induced upon adding salt, which lead to a decrease in the total amount of aligned water at the surface.

show abstract

Probing the Mineral–Water Interface with Nonlinear Optical Spectroscopy

Cited by 89 publications

References 112 publications

Role of Ions on the Surface-Bound Water Structure at the Silica/Water Interface: Identifying the Spectral Signature of Stability

Role of Ions on the Surface-Bound Water Structure at the Silica/Water Interface: Identifying the Spectral Signature of Stability

Water at charged interfaces

The Role of Ions on the Surface-Bound Water Structure at the Silica/Water Interface: Identifying the Spectral Signature of Stability

Contact Info

Product

Resources

About