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Efficient radioactive gas detection by scintillating porous metal–organic frameworks

Authors :
Orfano, M
Perego, J
Cova, F
Bezuidenhout, C
Piva, S
Dujardin, C
Sabot, B
Pierre, S
Mai, P
Daniel, C
Bracco, S
Vedda, A
Comotti, A
Monguzzi, A
Orfano, Matteo
Perego, Jacopo
Cova, Francesca
Bezuidenhout, Charl X.
Piva, Sergio
Dujardin, Christophe
Sabot, Benoit
Pierre, Sylvie
Mai, Pavlo
Daniel, Christophe
Bracco, Silvia
Vedda, Anna
Comotti, Angiolina
Monguzzi, Angelo
Orfano, M
Perego, J
Cova, F
Bezuidenhout, C
Piva, S
Dujardin, C
Sabot, B
Pierre, S
Mai, P
Daniel, C
Bracco, S
Vedda, A
Comotti, A
Monguzzi, A
Orfano, Matteo
Perego, Jacopo
Cova, Francesca
Bezuidenhout, Charl X.
Piva, Sergio
Dujardin, Christophe
Sabot, Benoit
Pierre, Sylvie
Mai, Pavlo
Daniel, Christophe
Bracco, Silvia
Vedda, Anna
Comotti, Angiolina
Monguzzi, Angelo
Publication Year :
2023

Abstract

Natural and anthropogenic gas radionuclides such as radon, xenon, hydrogen and krypton isotopes must be monitored to be managed as pathogenic agents, radioactive diagnostic agents or nuclear activity indicators. State-of-the-art detectors based on liquid scintillators suffer from laborious preparation and limited solubility for gases, which affect the accuracy of the measurements. The actual challenge is to find solid scintillating materials simultaneously capable of concentrating radioactive gases and efficiently producing visible light revealed with high sensitivity. The high porosity, combined with the use of scintillating building blocks in metal–organic frameworks (MOFs), offers the possibility to satisfy these requisites. We demonstrate the capability of a hafnium-based MOF incorporating dicarboxy-9,10-diphenylanthracene as a scintillating conjugated ligand to detect gas radionuclides. Metal–organic frameworks show fast scintillation, a fluorescence yield of ∼40%, and accessible porosity suitable for hosting noble gas atoms and ions. Adsorption and detection of 85Kr, 222Rn and 3H radionuclides are explored through a newly developed device that is based on a time coincidence technique. Metal–organic framework crystalline powder demonstrated an improved sensitivity, showing a linear response down to a radioactivity value below 1 kBq m−3 for 85Kr, which outperforms commercial devices. These results support the possible use of scintillating porous MOFs to fabricate sensitive detectors of natural and anthropogenic radionuclides.

Details

Database :
OAIster
Notes :
STAMPA, English
Publication Type :
Electronic Resource
Accession number :
edsoai.on1383765792
Document Type :
Electronic Resource