The neutron within the deuteron as a surrogate for neutron-induced reactions

TL;DR

This paper explores using deuteron-induced reactions as surrogates for neutron capture, linking theoretical models of inclusive breakup reactions with neutron momentum distributions to aid understanding of nucleosynthesis.

Contribution

It develops a theoretical framework connecting neutron surrogate reactions with neutron capture, incorporating momentum distribution analysis and approximations based on established inclusive breakup theories.

Findings

Derived an expression for proton yield in A(d,p)B reactions

Linked neutron momentum distribution to nucleon-nucleon force properties

Discussed implications for rapid neutron capture nucleosynthesis

Abstract

We propose the use of neutron poisons in reactions induced by radioactive beams as a test of theoretical models aiming to relate neutron capture in nuclei with neutron surrogate reactions such as (d,p) reactions. We exploit the approximations necessary to obtain a direct relation between the two reactions; surrogate vs. neutron capture. We also show how this is intimately related to the momentum distribution of the neutron within the deuteron. The models we use are based on the theory of inclusive breakup reactions commonly employed in the treatment of incomplete fusion and surrogate method. Such theories were developed in the 80's by Ichimura, Autern and Vincent [Phys. Rev. C 32, 431 (1985)], Udagawa and Tamura [Phys. Rev. C 24, 1348 (1981)] and Hussein and McVoy [Nucl. Phys. A 445, 124 (1985)]. We use these theories to derive an expression for the proton yield in the reaction A(d,p)B. The capture reaction $n + A \rightarrow B$ is then extracted using reasonable approximations. By recalling an old method proposed by Serber [Phys. Rev. 80, 1098 (1950); Nature 166, 709 (1950)] we explain how the momentum distribution of neutrons within the deuteron will depend on the short-range dependence of the nucleon-nucleon force. The relevance of our work to nucleosynthesis in the rapid neutron capture process is emphasized.