Microscopic study of 40Ca+58,64Ni fusion reactions

Abstract

Background: Heavy-ion fusion reactions at energies near the Coulomb barrier are influenced by couplings between the relative motion and nuclear intrinsic degrees of freedom of the colliding nuclei. The time-dependent Hartree-Fock (TDHF) theory, incorporating the couplings at the mean-field level, as well as the coupled-channels (CC) method are standard approaches to describe low energy nuclear reactions. Purpose: To investigate the effect of couplings to inelastic and transfer channels on the fusion cross sections for the reactions 40Ca+58Ni and 40Ca+64Ni. Methods: Fusion cross sections around and below the Coulomb barrier have been obtained from coupled-channels (CC) calculations, using the bare nucleus-nucleus potential calculated with the frozen Hartree-Fock method and coupling parameters taken from known nuclear structure data. The fusion thresholds and neutron transfer probabilities have been calculated with the TDHF method. Results: For 40Ca+58Ni, the TDHF fusion threshold is in agreement with the most probable barrier obtained in the CC calculations including the couplings to the low-lying octupole 31- state for 40Ca and to the low-lying quadrupole 21+ state for 58Ni. This indicates that the octupole and quadrupole states are the dominant excitations while neutron transfer is shown to be weak. For 40Ca+64Ni, the TDHF barrier is lower than predicted by the CC calculations including the same inelastic couplings as those for 40Ca+58Ni. TDHF calculations show large neutron transfer probabilities in 40Ca+64Ni which could result in a lowering of the fusion threshold. Conclusions: Inelastic channels play an important role in 40Ca+58Ni and 40Ca+64Ni reactions. The role of neutron transfer channels has been highlighted in 40Ca+64Ni.