Deformed shell model study of heavy N=Z nuclei and dark matter detection

Abstract

Deformed shell model (DSM) based on Hartree-Fock intrinsic states is applied to address two current problems of interest. Firstly, in the f5/2pg9/2 model space with jj44b effective interaction along with isospin projection, DSM is used to describe the structure of the recently observed low-lying T=0 and T=1 bands in the heavy odd-odd N=Z nucleus 66As. DSM results are close to the data and also to the shell model results. For the T=1 band, DSM predicts structural change at 8+ just as in the shell model. In addition, the lowest two T=0 bands are found to have quasi-deuteron structure above a 64Ge core and the 5+ and 9+ levels of the third T=0 band are found to be isomeric states. Secondly, in a first application of DSM to dark matter, detection rates for the lightest supersymmetric particle (a dark matter candidate) are calculated with 73Ge as the detector.