Mass measurements of $^{60-63}$Ga reduce X-ray burst model uncertainties and extend the evaluated $\mathbf{T=1}$ isobaric multiplet mass equation [CL]

We report precision mass measurements of neutron-deficient gallium isotopes approaching the proton drip line. The measurements of $^{60-63}$Ga performed with TITAN’s multiple-reflection time-of-flight mass spectrometer provide a more than threefold improvement over the current literature mass uncertainty of $^{61}$Ga and mark the first direct mass measurement of $^{60}$Ga. The improved precision of the $^{61}$Ga mass has important implications for the astrophysical rp-process, as it constrains essential reaction Q-values near the $^{60}$Zn waiting point. Based on calculations with a one-zone model, we demonstrate the impact of the improved mass data on prediction uncertainties of X-ray burst models. The first-time measurement of the $^{60}$Ga ground-state mass establishes the proton-bound nature of this nuclide; thus, constraining the location of the proton drip line along this isotopic chain. Including the measured mass of $^{60}$Ga enables us to extend the evaluated $T=1$ isobaric multiplet mass equation up to $A=60$.

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S. Paul, J. Bergmann, J. Cardona, et. al.
Mon, 29 Nov 21
26/94

Comments: 20 pages, 6 figures. Accepted for publication in Physical Review C