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A total scattering study of prenucleation structures in saturated aqueous magnesium sulfate: observation of extended clusters

A total scattering study of prenucleation structures in saturated aqueous magnesium sulfate: observation of extended clusters
A total scattering study of prenucleation structures in saturated aqueous magnesium sulfate: observation of extended clusters
Through a combination of X-ray and neutron total scattering and Empirical Potential Structure Refinement (EPSR) we explore the prenucleation structures of saturated aqueous magnesium sulfate. The atomistic model we present reveals a system characterised by isolated octahedral aquo magnesium species Mg(H2O)6, magnesium sulfate pairs (Mg(H2O)5SO4) and extended clusters built from corner-sharing MgO6 and SO4 polyhedra. Many of these features are directly observed in the crystal structures of the known solid form hydrates, including isolated polyhedra, corner sharing chains and rings, and it is only for the extended 3D polyhedral networks of the lower hydrates (mono- & di-) that no proto structures are observed in 2M solution. Looking at the average first solvation shell of the sulfate anion we see a complex and flexible environment that commonly includes water molecules brought into proximity by a coordinated hydrated magnesium. What emerges is a high probability that 10 water molecules will be observed in a combined tetrahedral/octahedral arrangement with a further 7 taking up more dispersed positions giving an average coordination of 17. The tendency for ions to aggregate into clusters allows areas of bulk water to exist that exhibit subtle differences in structure to that of pure water.
1463-9076
14898–14906
Irving, Daniel John Michael
10331d1d-01b3-4c0b-86fe-65c127dfd225
Light, Mark
cf57314e-6856-491b-a8d2-2dffc452e161
Rhodes, Matilda P.
5b1dfc30-bed4-42b8-89b7-ba0f3a6d86a6
Threlfall, Terrence
a7259124-36be-4615-a0d7-bef809adeed6
Headen, Thomas F.
2a4a7f24-225d-4e75-9a22-03ead84c3e02
Irving, Daniel John Michael
10331d1d-01b3-4c0b-86fe-65c127dfd225
Light, Mark
cf57314e-6856-491b-a8d2-2dffc452e161
Rhodes, Matilda P.
5b1dfc30-bed4-42b8-89b7-ba0f3a6d86a6
Threlfall, Terrence
a7259124-36be-4615-a0d7-bef809adeed6
Headen, Thomas F.
2a4a7f24-225d-4e75-9a22-03ead84c3e02

Irving, Daniel John Michael, Light, Mark, Rhodes, Matilda P., Threlfall, Terrence and Headen, Thomas F. (2023) A total scattering study of prenucleation structures in saturated aqueous magnesium sulfate: observation of extended clusters. Physical Chemistry Chemical Physics, 25 (21), 14898–14906. (doi:10.1039/D3CP01157G).

Record type: Article

Abstract

Through a combination of X-ray and neutron total scattering and Empirical Potential Structure Refinement (EPSR) we explore the prenucleation structures of saturated aqueous magnesium sulfate. The atomistic model we present reveals a system characterised by isolated octahedral aquo magnesium species Mg(H2O)6, magnesium sulfate pairs (Mg(H2O)5SO4) and extended clusters built from corner-sharing MgO6 and SO4 polyhedra. Many of these features are directly observed in the crystal structures of the known solid form hydrates, including isolated polyhedra, corner sharing chains and rings, and it is only for the extended 3D polyhedral networks of the lower hydrates (mono- & di-) that no proto structures are observed in 2M solution. Looking at the average first solvation shell of the sulfate anion we see a complex and flexible environment that commonly includes water molecules brought into proximity by a coordinated hydrated magnesium. What emerges is a high probability that 10 water molecules will be observed in a combined tetrahedral/octahedral arrangement with a further 7 taking up more dispersed positions giving an average coordination of 17. The tendency for ions to aggregate into clusters allows areas of bulk water to exist that exhibit subtle differences in structure to that of pure water.

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Accepted/In Press date: 12 May 2023
e-pub ahead of print date: 13 May 2023
Published date: 13 May 2023
Additional Information: Funding Information: The authors acknowledge the Science and Technology Facilities Council for the award of beamtime on SANDALS through beamtime request RB2000142,39 the use of the IRIDIS High Performance Computing Facility and associated support services at the University of Southampton and DJMI acknowledges the EPSRC for DTP funding (EP/R513325/1). Publisher Copyright: © 2023 The Royal Society of Chemistry.
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Identifiers

Local EPrints ID: 477368
URI: http://eprints.soton.ac.uk/id/eprint/477368
DOI: doi:10.1039/D3CP01157G
ISSN: 1463-9076
PURE UUID: 530cb5ef-f50d-4026-8fdc-ecd24f53f7c9
ORCID for Mark Light: ORCID iD orcid.org/0000-0002-0585-0843

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Date deposited: 05 Jun 2023 16:44
Last modified: 06 Jun 2024 01:37

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Contributors

Author: Daniel John Michael Irving
Author: Mark Light ORCID iD
Author: Matilda P. Rhodes
Author: Terrence Threlfall
Author: Thomas F. Headen

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