Issue 33, 2021

Structures of ions accommodated in salty ice Ih crystals

Abstract

Frozen aqueous electrolytes are ubiquitous and involved in various phenomena occurring in the natural environment. Although salts are expelled from ice during freezing of aqueous solutions, minor amounts of the constituent ions are accommodated in the crystal lattice of ice. This phenomenon was associated with the generation of the Workman–Reynolds freezing potential. Molecular simulations also confirmed the ion incorporation in the crystal lattice of ice Ih upon freezing of aqueous electrolytes and identified possible local structures of the ions. However, no experimental information is available on the structure of ions accommodated in the crystal lattice of ice Ih. In this work, we use X-ray absorption fine structure (XAFS) to study the local structures of K+ and Cl accommodated in ice Ih single crystals. Previous molecular simulations predicted that ions are trapped in the hexagonal cavities of the ice structure or replace two water molecules in the crystal lattice. Four possible configurations are considered and optimized by the calculations using ONIOM (QM/QM/QM). The results are evaluated in terms of the agreement between the experimental XAFS spectra and those simulated from the optimized structures. The spectra are most reasonably interpreted by assuming that K+ replaces one water molecule in the ice crystal lattice and is accommodated in a tetrahedral coordination cage. Similarly, Cl probably adopts the same configuration, because it explains the coordination number better than other structures, such as that assuming the replacement of two water molecules belonging to the same hexagonal planes.

Graphical abstract: Structures of ions accommodated in salty ice Ih crystals

Supplementary files

Article information

Article type
Paper
Submitted
14 Apr 2021
Accepted
20 Jul 2021
First published
20 Jul 2021

Phys. Chem. Chem. Phys., 2021,23, 17945-17952

Structures of ions accommodated in salty ice Ih crystals

Y. Yashima, Y. Okada, M. Harada and T. Okada, Phys. Chem. Chem. Phys., 2021, 23, 17945 DOI: 10.1039/D1CP01624E

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