Precise Q value measurements of 112,113Ag and 115Cd with the Canadian Penning trap for evaluation of potential ultra-low Q value β-decays

Abstract

An ultra-low Q value β-decay can occur from a parent nuclide to an excited state in the daughter with QUL <1 keV. These decays are of interest for nuclear β-decay theory and as potential candidates in neutrino mass determination experiments. To date, only one ultra-low Q value β-decay has been observed -- that of 115In with Qβ = 147(10) eV. A number of other potential candidates exist, but improved mass measurements are necessary to determine if the decays are energetically allowed and, in fact, ultra-low. We performed precise β-decay Q value measurements of 112,113Ag and 115Cd and combined them with nuclear energy level data for the daughter isotopes to determine if the potential UL Q value β-decay branches of 112,113Ag and 115Cd are energetically allowed and <1 keV. The Canadian Penning Trap at ANL was used to measure the cyclotron frequency ratios of singly-charged 112,113Ag and 115Cd ions with respect to their daughters. From these measurements, the ground-state β-decay Q values were obtained. The 112Ag, 113Ag, and 115Cd β-decay Q values were measured to be 3990.16(22) keV, 2085.7(4.6) keV, and 1451.36(34) keV, respectively. These results were compared to energies of excited states in 112Cd at 3997.75(14) keV, 113Cd at 2015.6(2.5) and 2080(10) keV, and 115In at 1448.787(9) keV, resulting in QUL values of --7.59(26) keV, 6(11) keV, and 2.57(34) keV, respectively. The potential UL Q value decays of 112Ag and 115Cd have been ruled out. 113Ag is still a possible candidate until a more precise measurement of the 2080(10) keV, 1/2+ state of 113Cd is available. In the course of this work we have found the ground state mass of 113Ag reported in the 2020AME to be lower than our measurement by 69(17) keV (a 4σ discrepancy).