6533b7cffe1ef96bd125952c
RESEARCH PRODUCT
Direct measurement of the mass difference of $^{72}$As-$^{72}$Ge rules out $^{72}$As as a promising $\beta$-decay candidate to determine the neutrino mass
Z. GeT. EronenA. De RoubinD.a. NesterenkoM. HukkanenO. BeliuskinaR. De GrooteS. GeldhofW. GinsA. KankainenÁ. KoszorúsJ. KotilaJ. KostensaloI.d. MooreA. RaggioS. Rinta-antilaJ. SuhonenV. VirtanenA.p. WeaverA. ZadvornayaA. Jokinensubject
nucleus: semileptonic decayexperimental methodsPenning trapenergy: ground stateelectron: captureElectroweak Interaction[PHYS.NEXP]Physics [physics]/Nuclear Experiment [nucl-ex]energy: transitionmass: spectrometernuclide: mass differenceneutrino: massNuclear Experimentexperimental resultsSymmetriesdescription
We report the first direct determination of the ground-state to ground-state electron-capture $Q$-value for the $^{72}$As to $^{72}$Ge decay by measuring their atomic mass difference utilizing the double Penning trap mass spectrometer, JYFLTRAP. The $Q$-value was measured to be 4343.596(75)~keV, which is more than a 50-fold improvement in precision compared to the value in the most recent Atomic Mass Evaluation 2020. Furthermore, the new $Q$-value was found to be 12.4(40)~keV (3.1 $\sigma$) lower. With the significant reduction of the uncertainty of the ground-state to ground-state $Q$-value value combined with the level scheme of $^{72}$Ge from $\gamma$-ray spectroscopy, we confirm that the five potential ultra-low $Q$-value ${\beta^{+}}$-decay or electron capture transitions are energetically forbidden, thus precluding all the transitions as possible candidates for the electron neutrino mass determination. However, the discovery of small negative $Q$-values opens up the possibility to use $^{72}$As for the study of virtual $\beta$-$\gamma$ transitions.
| year | journal | country | edition | language |
|---|---|---|---|---|
| 2021-03-15 |