Isomeric yield ratios and mass spectrometry of Y and Nb isotopes in the neutron-rich N=60 region: the unusual case of $^{98}$Y
Abstract
The isomeric yield ratio (IYR) of fission products is an observable that carries relevant information about the fragments emerging from the scission of a fissioning nucleus. We report on IYR of $^{96,98,100}$Y and $^{100,102}$Nb, together with the previously reported values for $^{97}$Y and $^{99}$Nb, produced in the 28 MeV $\alpha$-induced fission of $^{232}$Th at the Ion Guide Isotope Separation On-Line (IGISOL) facility of the University of Jyv{\"a}skyl{\"a}. We measured the IYR using two different techniques, the phase-imaging ion-cyclotron-resonance (PI-ICR) and the multiple-reflection time-of-flight mass spectrometry (MR-TOF-MS) methods. Moreover, we measured the masses of the long-lived isomeric states in $^{98,100}$Y and $^{100,102}$Nb populated via in-trap $\beta$-decay of their precursors. Since the $\beta$-decay selectively populates states with a favourable spin-parity, we could identify the measured state and show that in all cases except $^{102}$Nb the ground state is the low-spin state. This measurement confirms the spin-parity assignments of all the nuclei as they are reported on the ENSDF evaluations, disagreeing with the assignment for $^{100}$Y reported on the NUBASE2020 evaluation. Making also use of previously reported data, we observe an anomalously low IYR for the $N=59$ isotope $^{98}$Y as compared to other yttrium or neighboring niobium isotopes. This behavior is very rare across the nuclear chart and is posited to be connected to the characteristic shape coexistence of $^{98}$Y and to the change in the charge radii of the ground and excited states in the $N=58-60$ region.