Experimental study of the collision 11Be + 64Zn around the Coulomb barrier

Di Pietro A. Scuderi V. Moro A.M. Acosta L. Amorini F. Borge M.J.G. Figuera P. Fisichella M. Fraile L.M. Gomez-Camacho J. Gomez-Camacho J. Jeppesen H. Lattuada M. Martel I. Milin M. Musumarra A. Papa M. Pellegriti M.G. Pérez-Bernal F. Raabe R. Randisi G. Rizzo F. Scalia G. Tengblad O. Torresi D. Vidal A.M. Vidal A.M. Voulot D. Wenander F. Zadro M.
Physical Review C - Nuclear Physics
Doi 10.1103/PhysRevC.85.054607
Volumen 85
Citas: 105
In this paper details of the experimental procedure and data analysis of the collision of 11Be+64Zn around the Coulomb barrier are described and discussed in the framework of different theoretical approaches. In a previous work, the elastic scattering angular distribution of the collisions 9,10Be+64Zn as well as the angular distribution for the quasielastic scattering and transfer/breakup cross sections for the 11Be +64Zn reaction were briefly reported. The suppression of the quasielastic angular distribution in the Coulomb-nuclear interference angular region observed in the collision of the 11Be halo nucleus with respect to the other two beryllium isotopes was interpreted as being caused by a long-range absorption owing to the long decay length of the 11Be wave function. In this paper, new continuum-discretized coupled-channel calculations of the 11Be +64Zn reaction are reported in the attempt to interpret the effect of coupling with the breakup channels on the measured cross sections. The calculations show that the observed suppression of the Coulomb-nuclear interference peak is caused by a combined effect of Coulomb and nuclear couplings to the breakup channels. © 2012 American Physical Society.
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