6533b858fe1ef96bd12b61b3

RESEARCH PRODUCT

New Short-Lived IsotopeU221and the Mass Surface NearN=126

U. ForsbergShigeo MinamiCh. M. MrosekR.-d. HerzbergDaniel CoxT. Torres De HeidenreichNorbert WiehlMichael BlockBettina LommelPavel GolubevB. SchaustenJ. KrierLuis SarmientoI. PysmenetskaN. KurzJuha UusitaloA. HübnerJ. JeppssonV. YakushevaJoerg HoffmannL.-l. AnderssonJulia EvenDirk RudolphBirgit KindlerJ. SteinerA. K. MistryCh. E. DüllmannF. P. HeßbergerW. HartmannM. WegrzeckiEgon JägerH. BrandDieter AckermannAlexander YakushevH. SchaffnerJ. V. KratzMatthias SchädelMoumita MaitiJ. Khuyagbaatar

subject

PhysicsIsotopeIsotopes of uraniumAnalytical chemistryGeneral Physics and AstronomyNuclear fusionAlpha decayAtomic physicsRecoil separator

description

Two short-lived isotopes ^{221}U and ^{222}U were produced as evaporation residues in the fusion reaction ^{50}Ti+^{176}Yb at the gas-filled recoil separator TASCA. An α decay with an energy of E_{α}=9.31(5)  MeV and half-life T_{1/2}=4.7(7)  μs was attributed to ^{222}U. The new isotope ^{221}U was identified in α-decay chains starting with E_{α}=9.71(5)  MeV and T_{1/2}=0.66(14)  μs leading to known daughters. Synthesis and detection of these unstable heavy nuclei and their descendants were achieved thanks to a fast data readout system. The evolution of the N=126 shell closure and its influence on the stability of uranium isotopes are discussed within the framework of α-decay reduced width.

yearjournalcountryeditionlanguage
2015-12-10Physical Review Letters
https://doi.org/10.1103/physrevlett.115.242502