Ground-state and decay properties of neutron-rich Nb106

The ground-state properties of neutron-rich $^{106}\mathrm{Nb}$ and its $\ensuremath{\beta}$ decay into $^{106}\mathrm{Mo}$ have been studied using the CARIBU radioactive-ion-beam facility at Argonne National Laboratory. Niobium-106 ions were extracted from a $^{252}\mathrm{Cf}$ fission source and mass separated before being delivered as low-energy beams to the Canadian Penning Trap, as well as the X-Array and SATURN $\ensuremath{\beta}$-decay-spectroscopy station. The measured $^{106}\mathrm{Nb}$ ground-state mass excess of $\ensuremath{-}66202.0(13)$ keV is consistent with a recent measurement but has three times better precision; this work also rules out the existence of a second long-lived, $\ensuremath{\beta}$-decaying state in $^{106}\mathrm{Nb}$ above 5 keV in excitation energy. The decay half-life of $^{106}\mathrm{Nb}$ was measured to be 1.097(21) s, which is $8%$ longer than the adopted value. The level scheme of the decay progeny, $^{106}\mathrm{Mo}$, has been expanded up to $\ensuremath{\approx}4\phantom{\rule{4pt}{0ex}}\mathrm{MeV}$. The distribution of decay strength and considerable population of excited states in $^{106}\mathrm{Mo}$ of $J\ensuremath{\ge}3$ emphasizes the need to revise the adopted ${J}^{\ensuremath{\pi}}={1}_{}^{\ensuremath{-}}$ ground-state spin-parity assignment of $^{106}\mathrm{Nb}$; it is more likely to be $J\ensuremath{\ge}3$.