Fusion at the barrier with light radioactive ion beams Original Research Article

The experimental results recently obtained for fusion reactions at energies close to the Coulomb barrier with light radioactive (loosely bound) beams are reviewed and critically discussed. There have been two conflicting views on the effect of the loose binding of the projectile on the fusion cross section. On the one hand one expects an enhancement of the fusion cross section due to the loose binding while, on the other hand, the easy breakup of the projectile is expected to inhibit the fusion cross section. We critically discuss these two aspects of loose binding by comparing the experimental results for a number of radioactive beams. The data for 17F (where the last neutron binding energy View the MathML source MeV), neither show breakup effects nor enhancement when compared with the fusion of the nucleus 19F. The data for a 6He beam (View the MathML source MeV) show enhancement, very strong in one case, and the strong breakup (BU)+transfer cross section may be related to this. The fusion data obtained with the halo nucleus 11Be (View the MathML source MeV) do not show enhancement below the barrier, compared with 9Be, and show moderate effects above the barrier. Moreover, 9Be (View the MathML source MeV) shows a very strong BU+transfer cross section as in the case of 6He, but this apparently has no direct effect on fusion. The data with the neutron-rich 38S, 29,31Al radioactive beams do not differ much from data with the stable 32S, 27Al, respectively. In conclusion we observe: (i) effects of loose binding in neutron skin nuclei but not with other halo nuclei, (ii) a reduction of the fusion cross section above the barrier due to breakup effects. The various theoretical approaches developed up to now based on “simple” assumptions give opposite predictions for fusion, with some expecting enhancement of the cross section while others expect a hindrance of the cross section. However, most of these approaches do not correctly treat the transitions to the continuum which are expected to be induced easily in these weakly bound nuclei. It is necessary to develop a more complete and possibly “simple” theoretical treatment that incorporates the continuum coupling which will play an important role in subbarrier fusion.