KAMEO (Kaonic Atoms Measuring Nuclear Resonance Effects Observables) is a proposal for an experiment aiming to perform the first consistent measurement of the E2 nuclear resonance effects in kaonic molybdenum A=94,96,98,100 isotopes. The E2 nuclear resonance mixes atomic states, due to the electrical quadrupole excitation of nuclear rotational states. It occurs in atoms having the energy of a nuclear excitation state closely matching an atomic de-excitation state energy, and affects the rates of X-ray atomic transitions matching the energy of the resonance. The measurement E2 nuclear resonance effect in KMO isotopes allows the study of the strong kaon-nucleus interaction in a rotational excited nuclear state. Moreover, the effect enables the K- to access an inner atomic level not easily reachable by the kaon normal cascade, due to the nuclear absorption. The KAMEO proposed apparatus consists of 4 enriched Mo A=94, 96, 98, 100 isotope strips, exposed to the kaons produced by the DAΦNE collider, for kaonic atoms formation, with a highpurity germanium detector, cooled with liquid nitrogen, used to measure the X-ray atomic transitions. The DAΦNE collider is located at the National Laboratories of Frascati (LNF-INFN), in Italy. It is already suited for kaonic atoms measurement by the SIDDHARTA-2 collaboration.

De Paolis L., Abbene L., Bazzi M., Bettelli M., Borghi G., Bosnar D., et al. (2024). The measurement of the E2 nuclear resonance effects in kaonic atoms at DAΦNE: the KAMEO proposal. EPJ WEB OF CONFERENCES, 291 [10.1051/epjconf/202429105003].

The measurement of the E2 nuclear resonance effects in kaonic atoms at DAΦNE: the KAMEO proposal

Abbene L.;Buttacavoli A.;Principato F.;
2024-02-16

Abstract

KAMEO (Kaonic Atoms Measuring Nuclear Resonance Effects Observables) is a proposal for an experiment aiming to perform the first consistent measurement of the E2 nuclear resonance effects in kaonic molybdenum A=94,96,98,100 isotopes. The E2 nuclear resonance mixes atomic states, due to the electrical quadrupole excitation of nuclear rotational states. It occurs in atoms having the energy of a nuclear excitation state closely matching an atomic de-excitation state energy, and affects the rates of X-ray atomic transitions matching the energy of the resonance. The measurement E2 nuclear resonance effect in KMO isotopes allows the study of the strong kaon-nucleus interaction in a rotational excited nuclear state. Moreover, the effect enables the K- to access an inner atomic level not easily reachable by the kaon normal cascade, due to the nuclear absorption. The KAMEO proposed apparatus consists of 4 enriched Mo A=94, 96, 98, 100 isotope strips, exposed to the kaons produced by the DAΦNE collider, for kaonic atoms formation, with a highpurity germanium detector, cooled with liquid nitrogen, used to measure the X-ray atomic transitions. The DAΦNE collider is located at the National Laboratories of Frascati (LNF-INFN), in Italy. It is already suited for kaonic atoms measurement by the SIDDHARTA-2 collaboration.
16-feb-2024
Settore PHYS-06/A - Fisica per le scienze della vita, l'ambiente e i beni culturali
Settore PHYS-03/A - Fisica sperimentale della materia e applicazioni
17th International Workshop on Meson Physics, MESON 2023
KRAKÓW, POLAND
2023
17
De Paolis L., Abbene L., Bazzi M., Bettelli M., Borghi G., Bosnar D., et al. (2024). The measurement of the E2 nuclear resonance effects in kaonic atoms at DAΦNE: the KAMEO proposal. EPJ WEB OF CONFERENCES, 291 [10.1051/epjconf/202429105003].
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Utilizza questo identificativo per citare o creare un link a questo documento: https://hdl.handle.net/10447/667006
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