EPJ Web of Conferences (Jan 2023)

A technique for studying (n,p) reactions of astrophysical interest using radioactive beams with SECAR

  • Tsintari Pelagia,
  • Berg Georg P. A.,
  • Blackmon Jeff,
  • Chipps Kelly,
  • Couder Manoel,
  • Deibel Catherine,
  • Dimitrakopoulos Nikolaos,
  • Garg Ruchi,
  • Greife Uwe,
  • Hermansen Kirby,
  • Hood Ashley,
  • Jain Rahul,
  • Maher Cavan,
  • Marshall Caleb,
  • Meisel Zach,
  • Miskovich Sara,
  • Montes Fernando,
  • Perdikakis Georgios,
  • Pereira Jorge,
  • Ruland Thomas,
  • Schatz Hendrik,
  • Setoodehnia Kiana,
  • Smith Michael,
  • Wagner Louis,
  • Zegers Remco G. T.

DOI
https://doi.org/10.1051/epjconf/202327913005
Journal volume & issue
Vol. 279
p. 13005

Abstract

Read online

The formation of nuclei in slightly proton-rich regions of the neutrino-driven wind of core-collapse supernovae could be attributed to the neutrino-p process (νp-process). As it proceeds via a sequence of (p,γ) and (n,p) reactions, it may produce elements in the range of Ni and Sn, considering adequate conditions. Recent studies identify a number of decisive (n,p) reactions that control the efficiency of the νp-process. The study of one such (n,p) reaction via the measurement of the reverse (p,n) in inverse kinematics was performed with SECAR at NSCL/FRIB. Proton-induced reaction measurements, especially at the mass region of interest, are notably difficult since the recoils have nearly identical masses as the unreacted projectiles. Such measurements are feasible with the adequate separation level achieved with SECAR, and the in-coincidence neutron detection. Adjustments of the SECAR system for the first (p,n) reaction measurement included the development of new ion beam optics, and the installation of the neutron detection system. The aforementioned developments along with a discussion on the preliminary results of the p(58Fe,n)58Co reaction measurement are presented.