Single-neutron knockout from 20C and the structure of 19C

Abstract

The low-lying unbound level structure of the halo nucleus 19C has been investigated using single-neutron knockout from 20C on a carbon target at 280 MeV/nucleon. The invariant mass spectrum, derived from the momenta of the forward going beam velocity 18C fragment and neutrons, was found to be dominated by a very narrow near threshold (Erel = 0.036(1) MeV) peak. Two less strongly populated resonance-like features were also observed at Erel = 0.84(4) and 2.31(3) MeV, both of which exhibit characteristics consistent with neutron p-shell hole states. Comparisons of the energies, measured cross sections and parallel momentum distributions to the results of shell-model and eikonal reaction calculations lead to spin-parity assignments of 5/2+1 and 1/2-1 for the levels at Ex = 0.62(9) and 2.89(10) MeV with Sn = 0.58(9) MeV. Spectroscopic factors were also deduced and found to be in reasonable accord with shell-model calculations. The valence neutron configuration of the 20C ground state is thus seen to include, in addition to the known 1s21/2 component, a significant 0d25/2 contribution. The level scheme of 19C, including significantly the 1/2-1 cross-shell state, is well accounted for by the YSOX shell-model interaction developed from the monopole-based universal interaction.