Litcius/Paper detail

84-Nuclearity Lanthanide-Aluminum Cyclic Clusters: Promising Materials for Iodine Capture and Storage

Man-Ting Chen, Mingxuan Zhang, Qiaofei Xu, Gui‐Lin Zhuang, La‐Sheng Long, Lan‐Sun Zheng

2025Journal of the American Chemical Society17 citationsDOI

Abstract

Developing high-performance adsorbents for iodine uptake and storage has become an urgent priority for safe disposal and long-term storage of nuclear waste. In this work, two cyclic lanthanide-aluminum clusters with the formula [Ln 12 Al 72 (hmp) 60 (C 2 H 5 O 2 ) 6 (μ 2 –OH) 120 (μ 3 –OH) 18 (H 2 O) 30 ]Cl 24 ·(NO 3 ) 24 ·(H 2 O) x (Ln = Tb, x ≈ 80, Tb 12 Al 72; Ln = Gd, x ≈ 100, Gd 12 Al 72; Hhmp = 2-(hydroxymethyl)pyridine and C 2 H 6 O 2 = ethylene glycol) are reported. Single-crystal analysis reveals that its inner diameter is approximately 1.1 nm, with an outer diameter of 4.1 nm and a thickness of 3.1 nm. The packing of cyclic clusters through intermolecular interactions generates a 3D supramolecular structure with one-dimensional channels. Investigation of the iodine adsorption performance of the cluster indicates an uptake capacity of 3.14 g g –1 for Tb 12 Al 72 and 3.1 g g –1 for Gd 12 Al 72 . The effectiveness of iodine adsorption is largely due to the accessible micropore structure along with the high density of pyridine rings and abundant hydroxyl oxygen atoms. Consistently, DFT calculations indicate that the [Al(μ–OH) n ] clusters and pyridine ring regions synergistically facilitate iodine adsorption, effectively promoting the dissociation of I 2 into I – anions. This unique micropore environment enhances the electrostatic stabilization of polyiodide anions through a strong Coulombic attraction, significantly boosting the capture of iodine.

Topics & Concepts

ChemistryLanthanideIodineAluminiumOrganic chemistryIonRadioactive element chemistry and processingChemical Synthesis and CharacterizationCovalent Organic Framework Applications