Quenching of single-particle strength inferred from nucleon-removal transfer reactions on 15C

Abstract

The difference in the proton and neutron separation energies ( S) of the weakly bound 15C ground state is -19.86 MeV, an extreme value. Data from intermediate-energy heavy-ion induced (HI-induced) knockout reactions on nuclei spanning -20 S+20 MeV, suggest that the degree to which single-particle strength is quenched, Rs, has a negative correlation with S, decreasing from unity around -20~MeV to around 0.2 at +20~MeV. For the 15C ground state (Rs=0.96(4) in HI-induced knockout), contrasting results have recently been obtained via the neutron-adding transfer reaction, which reveal a value of Rs=0.64(15), similar to the value observed at modest S and more extreme values of S with reaction probes other than HI knockout. In order to explore the any potential differences between adding and removing processes in transfer reactions at extreme S, single-neutron removal transfer reactions on 15C were performed at 7.1MeV/u in inverse kinematics. The removal of a valence neutron in 2s1/2 orbit using both (p,d) and (d,t) reactions shows consistent quenching factors and agrees with those from the neutron-adding reaction. The present results, which can be compared with neutron knockout reaction, suggest that correlations, represented by the quenching factor, show limited dependence on neutron-proton asymmetry under the most extreme asymmetry conditions so far achieved in transfer reactions.