Unravelling the structural and dynamical properties of concentrated aqueous ammonium nitrate solutions: MD simulation studies

In this work, we present, the concentration-dependent solvation structure and dynamics of an ammonium nitrate (AN) ion pair in aqueous media by means of classical molecular dynamics simulations. Structural properties were investigated by computing the potentials of mean force (PMFs), radial distribution functions (RDFs), cluster size distribution functions, and hydrogen bond dynamics. The change in the depth of the contact ion pair (CIP) and solvent-separated ion pair minima (SSIP) is marginal, whereas for the solvent-assisted ion pair (SAIP) is more stable at lower salt concentrations. The marginal difference in the depth of the CIP minimum of the PMF is explained based on cluster size distribution and hydrogen bonding. The solvation structure of the ions is not affected by the salt concentration. Ab-initio and classical molecular dynamics simulations (both constrained and unconstrained) give similar results for the solvation structure around the cation and the anion. The spatial density distribution functions of the anions around the cations show that the anions occupy the space around the ammonium hydrogen atoms. Profound differences in dynamical properties are found in the case of concentrated solutions as compared to dilute solutions.

Automated summary

In this work, the solvation structure and dynamics of an ammonium nitrate (AN) ion pair in aqueous media were studied using classical molecular dynamics simulations. Concentration-dependent effects on the structure and dynamics were analyzed, and it was found that the solvation structure of the ions remains unaffected by the salt concentration. The study also revealed significant differences in dynamical properties between concentrated and dilute solutions.