First high-precision direct determination of the atomic mass of a superheavy nuclide evinces a new means to unambiguously determine atomic numbers.

2020 
Atoms of the superheavy element isotope $^{257}$Db ($Z$=105) were produced online in the fusion-evaporation reaction $^{208}$Pb($^{51}$V, 2n)$^{257}$Db. The gas-filled recoil ion separator GARIS-II was used to suppress both the unreacted primary beam and transfer products, prior to delivering the energetic beam of $^{257}$Db ions to a helium gas-filled ion stopping cell wherein they were thermalized. Thermalized $^{257}$Db$^{3+}$ ions were then transferred to a multi-reflection time-of-flight mass spectrograph for mass analysis. An alpha-particle detector embedded in the ion time-of-flight detector allowed disambiguation of the rare $^{257}$Db$^{3+}$ time-of-flight detection events from background by means of correlation with characteristic alpha-decays. Using 11 events where $\alpha$-decay and time-of-flight could be correlated to $^{257}$Db, a mass excess of $100\,063(231)_\textrm{stat}(2)_\textrm{sys}$~keV/c$^2$ could be determined. Comparing to several mass models, we show the technique can be used to unambiguously determine the atomic number as $Z$=105.
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