Investigation of the Structures and Energy Landscapes of Thiocyanate-Water Clusters

The Basin Hopping search method is used to find the global minima (GM) and map the energy landscapes of thiocyanate-water clusters, (SCN−)(H2O)n with 3-50 water molecules, with empirical potentials describing the ion-water and water-water interactions. (It should be noted that beyond n = 23, the low...

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Bibliographic Details
Published in:Inorganics 2017-06, Vol.5 (2), p.20
Main Authors: Smeeton, Lewis, Hey, John, Johnston, Roy
Format: Article
Language:English
Subjects:
Atomic structure
Clusters
Cubes
Density functional theory
Energy
energy landscapes
global optimisation
Heat conductivity
hydrated ions
Isomers
molecular clusters
Molecular structure
Nitrogen
Prisms
Sulfur
thiocyanate
Water chemistry
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Summary:The Basin Hopping search method is used to find the global minima (GM) and map the energy landscapes of thiocyanate-water clusters, (SCN−)(H2O)n with 3-50 water molecules, with empirical potentials describing the ion-water and water-water interactions. (It should be noted that beyond n = 23, the lowest energy structures were only found in 1 out of 8 searches so they are unlikely to be the true GM but are indicative low energy structures.) As for pure water clusters, the low energy isomers of thiocyanate-water clusters show a preponderance of fused water cubes and pentagonal prisms, with the weakly solvated thiocyanate ion lying on the surface, replacing two water molecules along an edge of a water polyhedron and with the sulfur atom in lower coordinated sites than nitrogen. However, by comparison with Density Functional Theory (DFT) calculations, the empirical potential is found to overestimate the strength of the thiocyanate-water interaction, especially O-H⋯S, with low energy DFT structures having lower coordinate N and (especially) S atoms than for the empirical potential. In the case of these finite ion-water clusters, the chaotropic (“disorder-making”) thiocyanate ion weakens the water cluster structure but the water molecule arrangement is not significantly changed.
ISSN:2304-6740
2304-6740
DOI:10.3390/inorganics5020020