A systematic study of exotic Sr isotopes using the β-Oslo Method: A CARIBU experiment
ORAL
Abstract
Understanding of neutron-induced reactions on nuclei far from stability has far-reaching implications for cosmogenic nucleosynthesis and fundamental nuclear physics. Presently, direct measurement of the radiative-capture cross section is experimentally inaccessible for these short-lived nuclei; however, indirect methods such as the β-Oslo method enable the experimental constraint of key nuclear properties that are inputs for reaction-theory calculations.
In particular, reaction rates on neutron-rich Sr isotopes directly in astrophysical abundances through processes that produce the heaviest elements present in the universe. We have performed an experiment at CARIBU at Argonne National Laboratory in order to determine the neutron-capture cross sections of 93,94,95Sr by constraining the γ-ray strength function (γSF) and nuclear level density (NLD). Low-energy Rb beams were transported to the Summing NaI(Tl) (SuN) detector where coincident β-γ events were measured. The γSF and NLD, properties extracted from the measured γ-ray spectra using the β-Oslo method, contribute the greatest uncertainty in Hauser-Feshbach calculations of neutron-capture reaction rates for short-lived neutron-rich nuclei. The experimental techniques and preliminary results of this work will be presented. Furthermore, the results of this work will shed light on nuclear structure properties for Sr isotopes, leading to significantly improved predictive reaction modeling.
In particular, reaction rates on neutron-rich Sr isotopes directly in astrophysical abundances through processes that produce the heaviest elements present in the universe. We have performed an experiment at CARIBU at Argonne National Laboratory in order to determine the neutron-capture cross sections of 93,94,95Sr by constraining the γ-ray strength function (γSF) and nuclear level density (NLD). Low-energy Rb beams were transported to the Summing NaI(Tl) (SuN) detector where coincident β-γ events were measured. The γSF and NLD, properties extracted from the measured γ-ray spectra using the β-Oslo method, contribute the greatest uncertainty in Hauser-Feshbach calculations of neutron-capture reaction rates for short-lived neutron-rich nuclei. The experimental techniques and preliminary results of this work will be presented. Furthermore, the results of this work will shed light on nuclear structure properties for Sr isotopes, leading to significantly improved predictive reaction modeling.
*Prepared by LLNL under Contract DE-AC52-07NA27344. This research used resources of ANL's ATLAS facility, which is a DOE Office of Science User Facility.
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Presenters
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Adriana Sweet
- University of California, Berkeley
- Lawrence Livermore National Laboratory