Production of Quasi-Stellar Neutron Field at Explosive Stellar Temperatures

Abstract

Neutron-induced reactions on unstable isotopes play a key role in the nucleosynthesis i--, r--, p--, rp-- and p--processes occurring in astrophysical scenarios. While direct cross section measurements are possible for long-living unstable isotopes using the neutron Time-of-Flight method, the currently available neutron intensities (≈106 n/s) require large samples which are not feasible for shorter lifetime isotopes. For the last four decades, the 7Li(p,n) reaction has been used to provide a neutron field at a stellar temperature of ≈ 0.3 GK with significantly higher intensity, allowing the successful measurement of many cross sections along the s-process path. In this paper we describe a novel method to use this reaction to produce neutron fields at temperatures of ≈ 1.5-3.5 GK, relevant to scenarios such as convective shell C/Ne burning, explosive Ne/C burning, and core-collapse supernovae. This method will allow direct cross section measurements of many important reactions at explosive temperatures, such as 26Al(n,p), 75Se(n,p) and 56Ni(n,p).