Issue 7, 2021

Stabilization of hydrated AcIII cation: the role of superatom states in actinium-water bonding

Abstract

225Ac-based radiopharmaceuticals have the potential to become invaluable in designated cancer therapy. However, the limited understanding of the solution chemistry and bonding properties of actinium has hindered the development of existing and emerging targeted radiotherapeutics, which also poses a significant challenge in the discovery of new agents. Herein, we report the geometric and electronic structural properties of hydrated AcIII cations in the [AcIII(H2O)n]3+ (n = 4–11) complexes in aqueous solution and gas-phase using density functional theory. We found that nine water molecules coordinated to the AcIII cation is the most stable complex due to an enhanced hydration Gibbs free energy. This complex adopts a closed-shell 18-electron configuration (1S21P61D10) of a superatom state, which indicates a non-negligible covalent character and involves H2O → AcIII σ donation interaction between s-/p-/d-type atomic orbitals of the Ac atom and 2p atomic orbitals of the O atoms. Furthermore, potentially existing 10-coordinated complexes need to overcome an energy barrier (>0.10 eV) caused by hydrogen bonding to convert to 9-coordination. These results imply the importance of superatom states in actinide chemistry generally, and specifically in AcIII solution chemistry, and highlight the conversion mechanism between different coordination numbers.

Graphical abstract: Stabilization of hydrated AcIII cation: the role of superatom states in actinium-water bonding

Supplementary files

Article information

Article type
Edge Article
Submitted
25 Apr 2020
Accepted
03 Jan 2021
First published
04 Jan 2021
This article is Open Access

All publication charges for this article have been paid for by the Royal Society of Chemistry
Creative Commons BY-NC license

Chem. Sci., 2021,12, 2655-2666

Stabilization of hydrated AcIII cation: the role of superatom states in actinium-water bonding

Y. Gao, P. Grover and G. Schreckenbach, Chem. Sci., 2021, 12, 2655 DOI: 10.1039/D0SC02342F

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