Potential enhancement of alpha decay in metals at cryogenic temperatures
- NázevTitle
- Potential enhancement of alpha decay in metals at cryogenic temperaturesPotential enhancement of alpha decay in metals at cryogenic temperatures
- Druh výsledkuResult type
- Článek v časopiseJournal article
- AutořiAuthors
- P. Belli, R.S. Boiko, F. Cappella, R. Chaplynskyi, F. Danevich, V. Tretyak
- DOIDOI
- 10.1140/epjp/s13360-026-07605-9
- Časopis / citaceJournal / citation
- EUROPEAN PHYSICAL JOURNAL PLUS. 2026, 141(3), 1-21. ISSN 2190-5444.
- RokYear
- 2026
- JazykLanguage
- eng
- WoSWoS
- 001730372700004
- ScopusScopus
- 2-s2.0-105035875741
- RIVRIV
- ProjektProject
- Laboratoire Souterrain de Modane - účast ČRLaboratoire Souterrain de Modane – participation of the Czech Republic; LSM-CZ III - Podzemní laboratoř LSM - účast České republiky - LM2023063 (2023–2026)LSM-CZ III - Podzemní laboratoř LSM - účast České republiky - LM2023063 (2023–2026)
AbstraktAbstract
The influence of metallic environments and cryogenic temperatures on nuclear decay rates remains an open question in nuclear physics, with potential implications for both fundamental science and radioactive waste management. Following a review of experimental studies on environmental effects in β decays, electron capture, and α decays, a phenomenological parametrization of electron screening effects is developed, taking into account competing theoretical predictions. The A-DREAM (Accelerated Depletion of RadioactivE wAste in Metals) project is then presented, aiming to investigate whether the α-decay rate of 226Ra can be enhanced at cryogenic temperatures when embedded in a metallic matrix. A wet-chemistry protocol was developed to produce low-activity (a few tens of Bq) sources of metallic 226Ra homogeneously incorporated into solid Ga-Hg alloy matrices, ensuring incorporation of Radium atoms into the metallic lattice in a structurally coherent manner, as well as long-term sample stability.
The influence of metallic environments and cryogenic temperatures on nuclear decay rates remains an open question in nuclear physics, with potential implications for both fundamental science and radioactive waste management. Following a review of experimental studies on environmental effects in β decays, electron capture, and α decays, a phenomenological parametrization of electron screening effects is developed, taking into account competing theoretical predictions. The A-DREAM (Accelerated Depletion of RadioactivE wAste in Metals) project is then presented, aiming to investigate whether the α-decay rate of 226Ra can be enhanced at cryogenic temperatures when embedded in a metallic matrix. A wet-chemistry protocol was developed to produce low-activity (a few tens of Bq) sources of metallic 226Ra homogeneously incorporated into solid Ga-Hg alloy matrices, ensuring incorporation of Radium atoms into the metallic lattice in a structurally coherent manner, as well as long-term sample stability.