Shell structure underlying the evolution of quadrupole collectivity in 38 S and 40 S probed by transient-field g-factor measurements on fast radioactive beams

The shell structure underlying shape changes in neutron-rich nuclei between N=20 and N=28 has been investigated by a novel application of the transient field technique to measure the first-excited state g factors in {sup 38}S and {sup 40}S produced as fast radioactive beams. Details of the new methodology are presented. In both {sup 38}S and {sup 40}S there is a fine balance between the proton and neutron contributions to the magnetic moments. Shell-model calculations that describe the level schemes and quadrupole properties of these nuclei also give a satisfactory explanation of the g factors. In {sup 38}S the g factor is extremely sensitive to the occupation of the neutron p{sub 3/2} orbit above the N=28 shell gap as occupation of this orbit strongly affects the proton configuration. The g factor of deformed {sup 40}S does not resemble that of a conventional collective nucleus because spin contributions are more important than usual.