Systematics of the first 2+ excitation in spherical nuclei with the Skryme quasiparticle random-phase approximation

We use the quasiparticle random-phase approximation (QRPA) and the Skyrme interactions SLy4 and SkM ∗ to systematically calculate energies and transition strengths for the lowest 2 + state in spherical even-even nuclei. The SkM ∗ functional, applied to 178 spherical nuclei between Z = 10 and 90, produces excitation energies that are on average 11% higher than experimental values, with residuals that fluctuate about the average by −35% to +55%. The predictions of SkM ∗ and SLy4 have significant differences, in part because of differences in the calculated ground state deformations; SkM ∗ performs better in both the average and dispersion of energies. Comparing the QRPA results with those of generator-coordinate-method (GCM) calculations, we find that the QRPA reproduces trends near closed shells better than the GCM, and that it overpredicts the energies less severely in general.