Neutron dominance in excited states of 26Mg and 10Be probed by proton and alpha inelastic scattering

Abstract

Isospin characters of nuclear excitations in 26Mg and 10Be are investigated via proton(p) and alpha(α) inelastic scattering. A structure model of antisymmetrized molecular dynamics (AMD) is applied to calculate the ground and excited states of 26Mg and 10Be. The calculation describes the isoscalar feature of the ground-band 2+1(Kπ=0+1) excitation and predicts the neutron dominance of the side-band 2+2(Kπ=2+) excitation in 26Mg and 10Be. The p and α inelastic scattering off 26Mg and 10Be is calculated by microscopic coupled-channel (MCC) calculations with a g-matrix folding approach by using the matter and transition densities of the target nuclei calculated with AMD. The calculation reasonably reproduces the observed 0+1, 2+1, and 2+2 cross sections of 26Mg+p scattering at incident energies Ep=24 and 40 MeV and of 26Mg+α scattering at Eα=104 and 120 MeV. For 10Be+p and 10Be+α scattering, inelastic cross sections to the excited states in the Kπ=0+1 ground-, Kπ=2+ side-, Kπ=0+2 cluster-, and Kπ=1- cluster-bands are investigated. The isospin characters of excitations are investigated via inelastic scattering processes by comparison of the production rates in the 10Be+p, 10Be+α, and 10C+p reactions. The result predicts that the 2+2 state is selectively produced by the 10Be+p reaction because of the neutron dominance in the 2+2 excitation as in the case of the 26Mg+p scattering to the 2+2 state, whereas its production is significantly suppressed in the 10C+p reaction.