Lifetimes of low-lying excited states in 8636Kr50

Abstract

The evolution of nuclear magic numbers at extremes of isospin is a topic at the forefront of contemporary nuclear physics. N=50 is a prime example, with increasing experimental data coming to light on potentially doubly-magic 100Sn and 78Ni at the proton-rich and proton-deficient extremes, respectively. Experimental discrepancies exist in the data for less exotic systems. In 86Kr the B(E2;2+1→0+1) value - a key indicator of shell evolution - has been experimentally determined by two different methodologies, with the results deviating by 3σ. Here, we report on a new high-precision measurement of this value, as well as the first measured lifetimes and hence transition strengths for the 2+2 and 3-(2) states in the nucleus. The Doppler-shift attenuation method was implemented using the TIGRESS gamma-ray spectrometer and TIGRESS integrated plunger (TIP) device. High-statistics Monte-Carlo simulations were utilized to extract lifetimes in accordance with state-of-the-art methodologies. Lifetimes of τ(2+1)=3364(stat.)20(sys.) fs, τ(2+2)=2639(stat.)19(sys.) fs and τ(3-(2))=736(stat.)32(sys.) fs were extracted. This yields a transition strength for the first-excited state of B(E2;2+1→0+)=2593(stat.)16(sys.) e2fm4. The measured lifetime disagrees with the previous Doppler-shift attenuation method measurement by more than 3σ, while agreeing well with a previous value extracted from Coulomb excitation. The newly extracted B(E2;2+1→0+1) value indicates a more sudden reduction in collectivity in the N=50 isotones approaching Z=40.