Molecular Resonance And Highly Deformed Fission Fragments In Si-28+Si-28

A high-resolution measurement of fragment-fragment-gamma triple coincidence events in the symmetric and near-symmetric mass exit channels from the Si-28+ Si-28 reaction has been undertaken using the EUROGAM Phase II gamma -ray spectrometer. The bombarding energy of E-lab(Si-28) = 111.6 MeV has been selected to populate the conjectured J(pi) = 38(+) quasimolecular resonance in the Ni-56 dinuclear system. In the Si-28+ Si-28 symmetric mass exit channel, the resonance behavior is clearly verified at the chosen energy. The population of highly excited states in the Mg-24, Si-28, and S-32 nuclei is discussed within a statistical fusion-fission model. Evidence is presented for selective population of states in the Si-28 fragments arising from the symmetric fission of the Ni-56 compound nucleus. The enhanced population of the K-pi=3(1)(-) band of the Si-28 nucleus, indicative of an oblate deformed shape, suggests that the oblate configuration plays a significant role in the resonant process. Fragment angular distributions for the elastic and low-lying inelastic channels as well as gamma -ray angular correlations for the mutual inelastic channel (2(+),2(+)) indicate that the spin orientations of the outgoing fragments are perpendicular to the orbital angular momentum. This unexpected result, which is different from the alignment found for the resonance structures in the Mg-24+ Mg-24 and C-12 + C-12 systems, suggests a situation where two oblate Si-28 nuclei interact in an equator-to-equator stable molecular configuration. A discussion concerning the spin alignment and spin disalignment for different reactions such as C-12 + C-12, Mg-24+Mg-24, and Si-28 + Si-28 is presented.