An electroluminescence emission detector to search for double-beta positron decays of /sup 124/Xe and /sup 78/Kr

“…The 2νβ + β + decay is expected to be several orders of magnitude slower [772]. It exhibits a unique signature with five point-like ionization clusters, located in the same plane with the central vertex [774].…”

A next-generation liquid xenon observatory for dark matter and neutrino physics

“…The 2νβ + β + decay is expected to be several orders of magnitude slower [772]. It exhibits a unique signature with five point-like ionization clusters, located in the same plane with the central vertex [774].…”

A next-generation liquid xenon observatory for dark matter and neutrino physics

“…The 2νβ + β + decay is expected to be several orders of magnitude slower [724]. It exhibits a unique signature with five point-like ionization clusters, located in the same plane with the central vertex [726].…”

A Next-Generation Liquid Xenon Observatory for Dark Matter and Neutrino Physics

“…Nevertheless, Kr is denser than Ar, much more inexpensive and presents even the highest absorption cross section for X-rays in the 14-34 keV energy range when compared to xenon. These are advantages when large detection volumes and/or high-pressure are requirements and in specific applications where its natural radioactivity background will not seriously affect its operation due to the high intensity of incident radiation, like in some x-and gamma-ray spectrometry applications, or the possibility of efficient background discrimination in rare-event detection [36][37][38][39]. Kr detectors have been already proposed for double-beta decay and double electron-capture detection [37][38][39].…”

A Gas Proportional Scintillation Counter with krypton filling