Ultra-low Qβ value for the allowed decay of 110Agm confirmed via mass measurements

Abstract

The mass of the electron-antineutrino can be determined in dedicated measurements of the β spectral shape near the β endpoint of a β- transition, with a low Q value enhancing the sensitivity of the measurement. One such low-Q-value candidate is the transition between the 6+ isomer of 110Ag and the 5+2 state in 110Cd (Qβ,m=-0.12(131) keV). To reduce the uncertainty of the Q value, we have used the phase-imaging ion-cyclotron-resonance technique with the JYFLTRAP double Penning trap and performed a high-precision atomic-mass measurement of 109Ag with 110Cd as a reference. Combined with the known spectroscopic data, we obtain a re-evaluated value Qβ,m=405(135) eV, for the 110Ag(6+m) → 110Cd(5+2) transition. This represents the lowest Qβ value for any allowed transition observed to date. In order to estimate the partial half-life (t1/2) and branching ratio (Br) of the transition, nuclear shell-model calculations were performed using the jj45pnb Hamiltonian in combination with state-of-the-art atomic calculations. The computed values t1/2 = 2.23+5.24-1.28 × 107 years and Br = 3.07+4.16-2.15 × 10-8, along with the thermal-neutron capture on stable 109Ag as a viable production method, make 110Agm a promising candidate for future antineutrino-mass measurements.