Neutron transition strengths of 2+1 states in the neutron rich Oxygen isotopes determined from inelastic proton scattering

Abstract

A coupled-channel analysis of the 18,20,22O(p,p') data has been performed to determine the neutron transition strengths of 2+1 states in Oxygen targets, using the microscopic optical potential and inelastic form factor calculated in the folding model. A complex density- and isospin dependent version of the CDM3Y6 interaction was constructed, based on the Brueckner-Hatree-Fock calculation of nuclear matter, for the folding model input. Given an accurate isovector density dependence of the CDM3Y6 interaction, the isoscalar (δ0) and isovector (δ1) deformation lengths of 2+1 states in 18,20,22O have been extracted from the folding model analysis of the (p,p') data. A specific N-dependence of δ0 and δ1 has been established which can be linked to the neutron shell closure occurring at N approaching 16. The strongest isovector deformation was found for 2+1 state in 20O, with δ1 about 2.5 times larger than δ0, which indicates a strong core polarization by the valence neutrons in 20O. The ratios of the neutron/proton transition matrix elements (Mn/Mp) determined for 2+1 states in 18,20O have been compared to those deduced from the mirror symmetry, using the measured B(E2) values of 2+1 states in the proton rich 18Ne and 20Mg nuclei, to discuss the isospin impurity in the 2+1 excitation of the A=18,T=1 and A=20,T=2 isobars.