PUBLICATION: PHYSICAL CHEMISTRY CHEMICAL PHYSICS

AUTHORS: Mu, LH; Yang, YZ; Liu, J; Du, W; Chen, JG; Shi, GS; Fang, HP

 

Cation-pi interactions are essential for many chemical, biological, and material processes, and these processes usually involve an aqueous salt solution. However, there is still a lack of a full understanding of the hydrated cation-pi interactions between the hydrated cations and the aromatic ring structures on the molecular level. Here, we report a molecular picture of hydrated cation-pi interactions, by using the calculations of density functional theory (DFT). Specifically, the graphene sheet can distort the hydration shell of the hydrated K+ to interact with K+ directly, which is hereafter called water-cation-pi interactions. In contrast, the hydration shell of the hydrated Li+ is quite stable and the graphene sheet interacts with Li+ indirectly, mediated by water molecules, which we hereafter call the cation-water-pi interactions. The behavior of hydrated cations adsorbed on a graphene surface is mainly attributed to the competition between the cation-pi interactions and hydration effects. These findings provide valuable details of the structures and the adsorption energy of hydrated cations adsorbed onto the graphene surface.

 

LINKS: http://dx.doi.org/10.1039/d1cp01609a