Abstract
The WS(2)/SiO(2) interface is of interest to a variety of research communities due to the electronic properties of WS(2) and the ubiquity of SiO(2) as a dielectric substrate. Due to the hydrophilic nature of silanol groups on the surface of SiO(2), water is difficult to remove at the surface, leading to confined water between WS(2) and SiO(2). Understanding the properties of confined water is important both fundamentally and for their effects on the interfacing materials. We investigated the structure and dynamics of confined water between WS(2) and SiO(2) using density functional theory and ab initio molecular dynamics, comparing it to adsorbed water on the surfaces of WS(2) and SiO(2). The results show that confined water becomes increasingly structured, with its orientation influenced by hydrogen bonding to the silanol groups as well as by the partial reorientation of water molecules to face WS(2) in an H-up configuration. The presence of silanol groups disrupts the hydrogen bonding network of water at monolayer coverage for both confined and unconfined water. For all interfaces explored, changes in both structural and dynamic properties are dependent on the number of water layers present.