The underground argon project: procurement and purification of argon for dark matter searches and beyond
Agnes, P. ; Back, H. O. ; Bonivento, W. ; Boulay, M. G. ; Canci, N. ; Caravati, M. ; Cebrian, S. (Universidad de Zaragoza) ; Cocco, V. ; Diaz Mairena, D. ; Franco, D. ; Gabriele, F. ; Gahan, D. ; Galbiati, C. ; Garcia Abia, P. ; Gendotti, A. ; Hessel, T. ; Horikawa, S. ; Lopez Manzano, R. ; Luzzi, L. ; Martinez, M. ; Pesudo, V. ; Razeti, M. ; Renshaw, A. L. ; Romero, L. ; Rubbia, A. ; Santorelli, R. ; Simeone, M. ; Stefanizzi, R. ; Steri, A. ; Sulis, S.
Resumen: The existence of dark matter in the universe is inferred from abundant astrophysical and cosmological observations. The Global Argon Dark Matter Collaboration (GADMC) aims to perform the searches for dark matter in the form of weakly interacting massive particles (WIMPs), whose collisions with argon nuclei would produce nuclear recoils with tens of keV energy. Argon has been considered an excellent medium for the direct detection of WIMPs as argon-based scintillation detectors can make use of pulse shape discrimination (PSD) to separate WIMP-induced nuclear recoil signals from electron recoil backgrounds with extremely high efficiency. However, argon-based direct dark matter searches must confront the presence of intrinsic 39Ar as the predominant source of electron recoil backgrounds (it is a beta-emitter with an endpoint energy of 565 keV and half-life of 269 years). Even with PSD, the 39Ar activity in atmospheric argon (AAr), mainly produced and maintained by cosmic ray-induced nuclear reactions, limits the ultimate size of argon-based detectors and restricts their ability to probe very-low-energy events. The discovery of argon from deep underground wells with significantly less 39Ar than that in AAr was an important step in the development of direct dark matter detection experiments using argon as the active target. Thanks to pioneering research and successful R&D, in 2012, the first 160 kg batch of underground argon (UAr) was extracted from a CO2 well in Cortez, Colorado. The DarkSide-50 experiment at the Gran Sasso National Laboratory (LNGS) in Italy, the first liquid argon detector ever operated with a UAr target, demonstrated a ∼ 1,400 suppression of the 39Ar activity with respect to the atmospheric argon. An even larger suppression is expected for 42Ar (another intrinsic beta-emitter with the 42K daughter isotope, also a beta-emitter) as its production is expected mainly in the upper atmosphere. Following the results of DarkSide-50, the GADMC initiated the UAr project for extraction from underground and cryogenic purification of 100 t of argon to be used as a target in the next-generation experiment DarkSide-20k. This paper contains a description of the Urania Plant in Cortez, Colorado, where UAr is extracted; the Aria Plant in Sardinia, Italy, an industrial-scale plant comprising a 350-m state-of-the-art cryogenic isotopic distillation column, designed for further purification of the extracted argon and further reduction of the isotopic abundance of 39Ar; and DArT, a facility for UAr radiopurity qualification at the Canfranc Underground Laboratory (LSC), Spain. Moreover, the high radiopurity of UAr leads to other possible applications, for instance, for those neutrinoless double-beta decay experiments using argon as shielding material or, more generally, for all those activities on argon-based detectors in high-energy physics or nuclear physics, which will be briefly discussed.
Idioma: Inglés
DOI: 10.3389/fphy.2024.1387069
Año: 2024
Publicado en: FRONTIERS IN PHYSICS 12 (2024), [7 pp.]
ISSN: 2296-424X
Factor impacto JCR: 2.1 (2024)
Categ. JCR: PHYSICS, MULTIDISCIPLINARY rank: 49 / 114 = 0.43 (2024) - Q2 - T2
Factor impacto CITESCORE: 4.6 - Mathematical Physics (Q1) - Physics and Astronomy (all) (Q2) - Biophysics (Q2) - Materials Science (miscellaneous) (Q2) - Physical and Theoretical Chemistry (Q3)
Factor impacto SCIMAGO: 0.483 - Mathematical Physics (Q2) - Materials Science (miscellaneous) (Q2) - Physics and Astronomy (miscellaneous) (Q2) - Physical and Theoretical Chemistry (Q2) - Biophysics (Q3)
Financiación: info:eu-repo/grantAgreement/ES/AEI/PID2022-138357NB-C22
Tipo y forma: Artículo (Versión definitiva)
Área (Departamento): Área Física Atóm.Molec.y Nucl. (Dpto. Física Teórica)
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Idioma: Inglés
DOI: 10.3389/fphy.2024.1387069
Año: 2024
Publicado en: FRONTIERS IN PHYSICS 12 (2024), [7 pp.]
ISSN: 2296-424X
Factor impacto JCR: 2.1 (2024)
Categ. JCR: PHYSICS, MULTIDISCIPLINARY rank: 49 / 114 = 0.43 (2024) - Q2 - T2
Factor impacto CITESCORE: 4.6 - Mathematical Physics (Q1) - Physics and Astronomy (all) (Q2) - Biophysics (Q2) - Materials Science (miscellaneous) (Q2) - Physical and Theoretical Chemistry (Q3)
Factor impacto SCIMAGO: 0.483 - Mathematical Physics (Q2) - Materials Science (miscellaneous) (Q2) - Physics and Astronomy (miscellaneous) (Q2) - Physical and Theoretical Chemistry (Q2) - Biophysics (Q3)
Financiación: info:eu-repo/grantAgreement/ES/AEI/PID2022-138357NB-C22
Tipo y forma: Artículo (Versión definitiva)
Área (Departamento): Área Física Atóm.Molec.y Nucl. (Dpto. Física Teórica)
Debe reconocer adecuadamente la autoría, proporcionar un enlace a la licencia e indicar si se han realizado cambios. Puede hacerlo de cualquier manera razonable, pero no de una manera que sugiera que tiene el apoyo del licenciador o lo recibe por el uso que hace. Exportado de SIDERAL (2026-01-12-13:05:36)
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Artículos > Artículos por área > Física Atómica, Molecular y Nuclear
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