Effects of the Spin-Orbit and Tensor Interactions on the M1 and E2 Excitations in Light Nuclei

Abstract

The effects of varying the spin-orbit and tensor components of a realistic interaction on M1 excitation rates and B(E2)'s are studied on nuclei in the 0p and 1s-0d shells. Not only the total M1 but also the spin and orbital parts separately are studied. The single-particle energies are first calculated with the same interaction that is used between the valence nucleons. Later this stringent condition is relaxed somewhat and the 1s level is raised relative to 0d. For nuclei up to 28Si, much better results i.e stronger B(M1) rates are obtained by increasing the strength of the spin-orbit interaction relative to the free value. This is probably also true for 32S, but 36Ar presents some difficulties. The effects of weakening the tensor interaction are also studied. On a more subtle level, the optimum spin-orbit interaction in the lower half of the s-d shell, as far as M1 excitations are concerned, is substantially larger than the difference E(J=3/2+)1-E(J=5/2+)1=5.2~MeV in 17O. A larger spin-orbit splitting is also needed to destroy the triaxiality in 22Ne. Also studied are how much M1 orbital and spin strength lies in an observable region and how much is buried in the grass at higher energies. It is noted that for many nuclei the sum B(M1)orbital+B(M1)spin is very close to B(M1)total, indicating that the summed cross terms are very small.

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