Complete fusion of 9Be with spherical targets

Abstract

The complete fusion of 9Be with 144Sm and 208Pb targets is calculated in the coupled-channels approach. The calculations include couplings between the 3/2-, 5/2-, and 7/2- states in the K=3/2 ground state rotational band of 9Be. It is shown that the B(E2) values for the excitation of these states are accurately described in the rotor model. The interaction of the strongly deformed 9Be nucleus with a spherical target is calculated using the double-folding technique and the effective M3Y interaction, which is supplemented with a repulsive term that is adjusted to optimize the fit to the data for the 144Sm target. The complete fusion is described by in-going-wave boundary conditions. The decay of the unbound excited states in 9Be is considered explicitly in the calculations by using complex excitation energies. The model gives an excellent account of the complete fusion (CF) data for 9Be+144Sm, and the cross sections for the decay of the excited states are in surprisingly good agreement with the incomplete fusion (ICF) data. Similar calculations for 9Be+208Pb explain the total fusion data at high energies but fail to explain the CF data, which are suppressed by 20%, and the calculated cross section for the decay of excited states is a factor of three smaller than the ICF data at high energies. Possible reasons for these discrepancies are discussed.