Abstract
The Transfer to the Continuum method has been applied to describe the 11Li(p, pn) and 14Be(p, pn) reactions in inverse kinematics, using structure overlaps computed within a full three-body model for the projectile. Calculations agree with the available experimental data on the unbound 10Li and 13Be nuclei.
Highlights
Nuclear systems at the limit of stability display exotic properties which have motivated extensive theoretical and experimental developments
The properties of the unbound core + n nuclei shape the structure of two-neutron halos, with the correlation between the valence neutrons playing a key role in binding the system [2]
Transfer to the Continuum (TC) The core + n relative-energy spectra and momentum distributions in (p, pn) knockout reactions can be computed within the Transfer to the Continuum (TC) framework [3], which was recently extended to the case of three-body projectiles [4]
Summary
Nuclear systems at the limit of stability display exotic properties which have motivated extensive theoretical and experimental developments. Transfer to the Continuum (TC) The core + n relative-energy spectra and momentum distributions in (p, pn) knockout reactions can be computed within the Transfer to the Continuum (TC) framework [3], which was recently extended to the case of three-body projectiles [4].
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