Ústav technické a experimentální fyziky Institute of Experimental and Applied Physics

Atomic corrections for the unique first-forbidden β transition of 187Re

NázevTitle
Atomic corrections for the unique first-forbidden β transition of 187ReAtomic corrections for the unique first-forbidden β transition of 187Re
Druh výsledkuResult type
Článek v časopiseJournal article
AutořiAuthors
O. Nitescu, R. Dvornicky, F. Šimkovic
DOIDOI
10.1103/PhysRevC.109.025501
Časopis / citaceJournal / citation
PHYSICAL REVIEW C. 2024, 109(2), ISSN 2469-9985.
RokYear
2024
JazykLanguage
eng
WoSWoS
001183159900001
ScopusScopus
2-s2.0-85187245572
RIVRIV
RIV/68407700:21670/24:00381085!RIV25-MSM-21670___
ProjektProject
Inženýrské aplikace fyziky mikrosvětaEngineering applications of microworld physics

AbstraktAbstract

In this paper, we re-examine one of the most promising candidates for determining the neutrino mass scale- the unique first forbidden beta transition from 187Re(5/2+) to 187Os(1/2-). With the lowest -known ground -state to ground -state Q value for a beta transition at 2.4709 keV, rhenium's beta decay can offer insights into the neutrino mass scale puzzle. However, understanding its electron spectrum is a complex task. Besides involving a mixture of s1/2 -state and p3/2 -state electrons, the rhenium beta spectrum could be strongly influenced by various atomic corrections. In addition to our previous paper [R. DvornickATIN SMALL LETTER Y WITH ACUTE, K. Muto, F. Simkovic, and A. Faessler, Phys. Rev. C 83, 045502 (2011)], we have incorporated finite nuclear size, diffuse nuclear surface, screening, and exchange corrections into the rhenium beta decay model. We have accounted for the last two effects within the framework of the Dirac-Hartree-Fock-Slater self -consistent method. We have discovered that both screening and exchange effects significantly alter the partial decay rates for the s1/2- and p3/2 -state emission channels, while still maintaining the experimentally confirmed dominance of the p3/2 -state emission. The ratio between the respective decay rates has been found to be approximately 104. When compared to the other corrections, the exchange effect stands out due to the modification it induces in the spectrum shape. We demonstrate that calculations with and without the exchange effect lead to entirely different shape factors for the decay spectrum. Finally, we illustrate that to preserve the linearity of the Kurie plot, it is essential to include the exchange correction in its definition. We conclude that atomic effects, especially the exchange effect, should be taken into account in current and future investigations of the neutrino mass scale from beta decays.

In this paper, we re-examine one of the most promising candidates for determining the neutrino mass scale- the unique first forbidden beta transition from 187Re(5/2+) to 187Os(1/2-). With the lowest -known ground -state to ground -state Q value for a beta transition at 2.4709 keV, rhenium's beta decay can offer insights into the neutrino mass scale puzzle. However, understanding its electron spectrum is a complex task. Besides involving a mixture of s1/2 -state and p3/2 -state electrons, the rhenium beta spectrum could be strongly influenced by various atomic corrections. In addition to our previous paper [R. DvornickATIN SMALL LETTER Y WITH ACUTE, K. Muto, F. Simkovic, and A. Faessler, Phys. Rev. C 83, 045502 (2011)], we have incorporated finite nuclear size, diffuse nuclear surface, screening, and exchange corrections into the rhenium beta decay model. We have accounted for the last two effects within the framework of the Dirac-Hartree-Fock-Slater self -consistent method. We have discovered that both screening and exchange effects significantly alter the partial decay rates for the s1/2- and p3/2 -state emission channels, while still maintaining the experimentally confirmed dominance of the p3/2 -state emission. The ratio between the respective decay rates has been found to be approximately 104. When compared to the other corrections, the exchange effect stands out due to the modification it induces in the spectrum shape. We demonstrate that calculations with and without the exchange effect lead to entirely different shape factors for the decay spectrum. Finally, we illustrate that to preserve the linearity of the Kurie plot, it is essential to include the exchange correction in its definition. We conclude that atomic effects, especially the exchange effect, should be taken into account in current and future investigations of the neutrino mass scale from beta decays.