Abstract
We have recently constructed two very successful n-\(^9\)Be optical potentials (Bonaccorso and Charity in Phys Rev C89:024619, 2014). One by the Dispersive Optical Model (DOM) method and the other (AB) fully phenomenological. The two potentials have strong surface terms in common for both the real and the imaginary parts. This feature makes them particularly suitable to build a single-folded (light-) nucleus-\(^9\)Be optical potential by using ab-initio projectile densities such as those obtained with the VMC method (Wiringa http://www.phy.anl.gov/theory/research/density/). On the other hand, a VMC density together with experimental nucleon–nucleon cross-sections can be used also to obtain a neutron and/or proton-\(^9\)Be imaginary folding potential. We will use here an ab-initio VMC density (Wiringa http://www.phy.anl.gov/theory/research/density/) to obtain both a n-\(^9\)Be single-folded potential and a nucleus-nucleus double-folded potential. In this work we report on the cases of \(^8\)B, \(^8\)Li and \(^8\)C projectiles. Our approach could be the basis for a systematic study of optical potentials for light exotic nuclei scattering on such light targets. Some of the projectiles studied are cores of other exotic nuclei for which neutron knockout has been used to extract spectroscopic information. For those cases, our study will serve to make a quantitative assessment of the core-target part of the reaction description, in particular its localization.
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The work of R.J. Charity was supported by the U.S. Department of Energy, Office of Science, Office of Nuclear Physics under Award No. DE-FG02-87ER-4036.
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Bonaccorso, A., Carstoiu, F., Charity, R.J. et al. Differences Between a Single- and a Double-Folding Nucleus-\(^\mathbf{9}\)Be Optical Potential . Few-Body Syst 57, 331–336 (2016). https://doi.org/10.1007/s00601-016-1082-4
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DOI: https://doi.org/10.1007/s00601-016-1082-4