期刊
JOURNAL OF PHYSICAL CHEMISTRY A
卷 125, 期 40, 页码 8899-8906出版社
AMER CHEMICAL SOC
DOI: 10.1021/acs.jpca.1c07206
关键词
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资金
- Centre for High Performance Computing at the University of Utah
- R. Gaurth Hansen Professorship fund
- Stephen Bialkowski Award in Environmental Chemistry funds
Investigation of the process of NO3- anion solvation using particle swarm optimization technique and density functional theory revealed the crucial role of charge transfer in the stabilization of species. At low concentrations, NO3- species tend to be located on the surface of water solution, while contact ion pair K+-NO3- undergoes rapid dissociation. This could result in oppositely signed concentration gradients for NO3- and K+ ions in a thin water film.
Investigation of the process of the NO3- anion solvation is central to understanding the chemical and physical properties of its aqueous solutions. The importance of this topic can be seen in atmospheric chemistry, as well as in nuclear waste processing research. In this work, we used a particle swarm optimization technique driven by density functional theory to sample the potential energy surface of various microsolvated [NO3 center dot(H2O)(n)](-) (n = 1-12) clusters. We found that the charge transfer plays a crucial role in the stabilization of the investigated species. Moreover, by conducting ab initio molecular dynamics simulations, we showed that at low concentrations (similar to 0.2 M) the NO3- species tend to be located on the surface of water solution. We also observed that the contact ion pair K+-NO3- undergoes a fast dissociation and each of the ions is solvated separately. As a result, from our calculations, we expect that at low concentration there could be oppositely signed concentration gradients for NO3- and K+ ions in a thin water film.
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