Gas molecules sandwiched in hydration layers at graphite/water interfaces.

Hideaki Teshima,Qin-Yi Li,Yasuyuki Takata,Koji Takahashi

doi:10.1039/d0cp01719a

Abstract

Hydration structures are ubiquitous at solid/liquid interfaces and play a key role in various physicochemical and biological phenomena. Recently, it has been reported that dissolved gas molecules attracted to hydrophobic surfaces form adsorbed gas layers. Although a hydration structure and adsorbed gas layers coexist on the surface, the relationships between them remain unknown. In this study, we investigated a highly ordered pyrolytic graphite/pure water interface with and without adsorbed gas layers using frequency-modulation atomic force microscopy. We penetrated the adsorbed gas layers with the strong load force of the AFM tip and thereby obtained the frequency shift curves inside them. By comparing the curves with those measured on a bare HOPG surface, we found that the adsorbed gas layers were located at regions where the molecular density of water was low and were sandwiched between hydration layers with high water density. Moreover, the distance between adjacent hydration layers was larger than that predicted by simulations and was the same with and without the adsorbed gas layers. We propose that gas molecules on the hydrophobic surface interact with the hydration structure before forming the adsorbed gas layers, and extend the distance between hydration layers.

Highlights

It has been reported based on atomic force microscopy (AFM) measurements that the distance between adjacent hydration layers on hydrophobic surfaces is larger than that on hydrophilic surfaces
Schlesinger and Sivan reported that the distance between hydration layers on the hydrophobic surface changed before and after the degassing of the solution, which strongly suggests a relationship between the dissolved gas molecules and the hydration structure.[16]
By comparing the curves with those obtained on a bare highly ordered pyrolytic graphite (HOPG) surface, we revealed the relationship between the adsorbed gas layers and the hydration structure

Summary

Introduction

It has been reported based on AFM measurements that the distance between adjacent hydration layers on hydrophobic surfaces is larger than that on hydrophilic surfaces. Attracts dissolved gas molecules and create nanoscopic gasenrichment layers on the hydrophobic surface It was revealed using high-sensitivity AFM that the gas-enrichment layers have the height of a few nanometers or less and can take several shapes, such as a row-like ordered gas layer,[16,17,29,30,31,32,33] and a disordered gas layer covering the ordered gas layers.[30,33] these adsorbed gas layers and the hydration structure exist in the same region, a concrete relationship between them, which is essential for understanding fundamental phenomena at solid/liquid interfaces, remains unclear.

Results and discussion

Conclusions

Conflicts of interest