Abstract
We propose to use the Continuum Discretized Coupled Channels (CDCC) formalism to build some evaluations of deuteron induced reactions. In particular a semi-microscopic model based upon the CDCC-DWBA framework is used to compute the (d,p) cross sections. We have then built a functional to reproduce these calculations and we have included it into Talys. As an illustration, some excitation functions for d+Ni reactions have been compared with the experimental data: a good agreement between experimental cross sections and the calculated ones is then obtained.
Highlights
Deuteron induced reactions are relevant to produce some isotopes usefull for medical or material applications
Since a large part of the (d,p) reaction is expected to come from direct interaction, we propose to build a semi-microscopic model relying on Continuum Discretized Coupled Channels (CDCC)-DWBA calculations to get the excitation function of this transfer reaction
Ln, jn meaning that the (d,p) excitation function can be approximated by a linear combination of the individual cross sections, σlcnd,cjnc,id0wba
Summary
Deuteron induced reactions are relevant to produce some isotopes usefull for medical or material applications. Since a large part of the (d,p) reaction is expected to come from direct interaction, we propose to build a semi-microscopic model relying on CDCC-DWBA calculations to get the excitation function of this transfer reaction.
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