Investigation of potential ultra-low Q-value β-decay candidates 89Sr and 139Ba using Penning trap mass spectrometry

Abstract

Background: Ultra-low Q-value β-decays are interesting processes to study with potential applications to nuclear β-decay theory and neutrino physics. While a number of potential ultra-low Q-value β-decay candidates exist, improved mass measurements are necessary to determine which are energetically allowed. Method: Penning trap mass spectrometry was used to determine the atomic mass of 89Y and 139La, from which β-decay Q-values for 89Sr and 139Ba were obtained to determine if there could be an ultra-low Q-value decay branch in the β-decay of 89Sr → 89Y or 139Ba → 139La. Results: The 89Sr → 89Y and 139Ba → 139La β-decay Q-values were measured to be QSr = 1502.20(0.35) keV and QBa = 2308.37(68) keV. These were compared to energies of excited states in 89Y at 1507.4(1) keV, and in 139La at 2310(19) keV and 2313(1) keV to determine Q-values of -5.20(37) keV for the potential ultra-low β-decay branch of 89Sr and -1.6(19.0) keV and -4.6(1.2) keV for those of 139Ba. Conclusion: The potential ultra-low Q-value decay branch of 89Sr to the 89Y (3/2-, 1507.4 keV) state is energetically forbidden and has been ruled out. The potential ultra-low Q-value decay branch of 139Ba to the 2313 keV state in 139La with unknown Jπ has also been ruled out at the 4σ level, while more precise energy level data is needed for the 139La (1/2+, 2310 keV) state to determine if an ultra-low Q-value β-decay branch to this state is energetically allowed.