Decay of excited nuclei produced in 78,82Kr + 40Ca reactions at 5.5 MeV/nucleon

Abstract

Decay modes of excited nuclei are investigated in 78,82Kr + 40Ca reactions at 5.5 MeV/nucleon. Charged products were measured by means of the 4π INDRA array. Kinetic-energy spectra and angular distributions of fragments with atomic number 3 Z 28 indicate a high degree of relaxation and are compatible with a fission-like phenomenon. Persistence of structure effects is evidenced from elemental cross-sections (σZ) as well as a strong odd-even-staggering (o-e-s) of the light-fragment yields. The magnitude of the staggering does not significantly depend on the neutron content of the emitting system. Fragment-particle coincidences suggest that the light partners in very asymmetric fission are emitted either cold or at excitation energies below the particle emission thresholds. The evaporation residue cross-section of the 78Kr + 40Ca reaction is slightly higher than the one measured in 82Kr + 40Ca reaction. The fission-like component is larger by 25% for the reaction having the lowest neutron-to-proton ratio. These experimental features are confronted to the predictions of theoretical models. The Hauser-Feshbach approach including the emission of fragments up to Z = 14 in their ground states as well as excited states does not account for the main features of σZ. For both reactions, the transition-state formalism reasonably reproduces the Z-distribution of the fragments with charge 12 Z 28. However, this model strongly overestimates the light-fragment cross-sections and does not explain the o-e-s of the yields for 6 Z 10. The shape of the whole Z-distribution and the o-e-s of the light-fragment yields are satisfactorily reproduced within the dinuclear system framework which treats the competition between evaporation, fusion-fission and quasifission processes. The model suggests that heavy fragments come mainly from quasifission while light fragments are predominantly populated by fusion. An underestimation of the cross sections for 16 Z 22 could signal a mechanism in addition to the capture process.