Microsolvation of Sr2+ , Ba2+: Structures, energies, bonding, and nuclear magnetic shieldings

Abstract

An exhaustive exploration using non–relativistic and four–component relativistic formalisms of the potential energy surfaces for the microsolvation of Sr2+, Ba2+ with up to n = 6 water molecules is presented in this work. A multitude of well defined local minima stabilized by cation ⋯ water and by water ⋯ water interactions are found. Cation ⋯ water contacts transcend the electrostatic interactions of simplistic ionic bonding. The formal charge causes a chaotropic effect in the structure of the solvent affecting water to water hydrogen bonds and inducing water dissociation and microsolvation of the resulting H+, OH− ions in extreme cases. Relativistic effects are close to 0.7% or smaller in geometries and electronic energies, but they are around 27% for shieldings of Ba2+ clusters. The nuclei of the central cations are deshielded (around 10% in going from (Formula presented.) to (Formula presented.)) due to microsolvation.