Insoluble Acyclic Cucurbitnuril-Type Receptors Capture Iodine from the Vapor Phase

Nuclear energy makes large contributions toward meeting global energy needs, but societal concerns remain high given the impacts of the intended release of radioactive materials including 129I and 131I. In this paper we explore the use of a homologous series of acyclic CB[n] type hosts (H1-H4) as ad...

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Published in:Chemistry : a European journal 2024-11, Vol.30 (65), p.e202403176
Main Authors: Perera, Suvenika, Shaurya, Alok, Zeppuhar, Andrea, Chen, Fu, Zavalij, Peter Y, Gaskell, Karen, Isaacs, Lyle
Format: Article
Language:English
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Summary:Nuclear energy makes large contributions toward meeting global energy needs, but societal concerns remain high given the impacts of the intended release of radioactive materials including 129I and 131I. In this paper we explore the use of a homologous series of acyclic CB[n] type hosts (H1-H4) as adsorbents of iodine from the vapor phase. We find that H2-H4, but not H1 - perform well in this application with uptake capacities of 2.2 g g-1, 1.5 g g-1, and 1.9 g g-1, respectively. The chemisorptive uptake process involves partial oxidation of catechol walled H2 to quinone walled host and capture of I3 - and I5 -. Solid H2 can be regenerated by treatment with Na2S2O4 and reused at least five times. The x-ray crystal structure of H2 is also reported.Nuclear energy makes large contributions toward meeting global energy needs, but societal concerns remain high given the impacts of the intended release of radioactive materials including 129I and 131I. In this paper we explore the use of a homologous series of acyclic CB[n] type hosts (H1-H4) as adsorbents of iodine from the vapor phase. We find that H2-H4, but not H1 - perform well in this application with uptake capacities of 2.2 g g-1, 1.5 g g-1, and 1.9 g g-1, respectively. The chemisorptive uptake process involves partial oxidation of catechol walled H2 to quinone walled host and capture of I3 - and I5 -. Solid H2 can be regenerated by treatment with Na2S2O4 and reused at least five times. The x-ray crystal structure of H2 is also reported.
ISSN:1521-3765
1521-3765
DOI:10.1002/chem.202403176