Abstract: Near the doubly-magic nucleus Ni-78 (Z = 28, N = 50), there has been a decades-long debate on the existence of a long-lived isomer in Cu-76. A recent mass measurement claimed to have settled the debate, by measuring the energy of the isomer and shedding light on the structure of the nucleus. In this work, we present new, more accurate, and precise values of the half-lives of the isomeric and ground states in Cu-76. Our findings suggest that both states have very similar half-lives, in the 600-700 ms range, in disagreement with the literature values, implying that they cannot be differentiated by their decay curves. These results raise more questions than they answer, reopening the debate and showing that the structures in Cu-76 are still not fully understood.

Abstract: The neutron-rich rare isotope W-190 is discussed as a candidate for a prolate-oblate transitional nucleus with maximum gamma-softness. The collectivity of this isotope is assessed for the first time by the measurement of the reduced E2 transition probability of its first 2(+) state to the ground state. The experiment employed the FAst TIming Array (FATIMA), comprised of 36 LaBr3(Ce) scintillators, which was part of the DESPEC setup at GSI, Darmstadt. The 4(1)(+) and 2(1)(+) states of W-190 were populated subsequently to the decay of its 127(12) μs isomeric J(pi )= 10(-) state. The mean lifetime of the 2(1)(+) state was determined to be tau = 274(28) ps, which corresponds to a B(E2; 2(1)(+ )-> 0(1)(+)) value of 95(10) W.u. The results motivated a revision of previous calculations within an energy-density functional-based interacting boson model-2 approach, yielding E2 transition properties and spectroscopic quadrupole moments for tungsten isotopes. From comparison to theory, the new data suggest that W-190 is at the transition from prolate to oblate structure along the W isotopic chain, which had previously been discussed as a nuclear shape-phase transition.