Investigation of the 57Ni(p,γ)58Cu reaction in the νp process

Sean Patrick Byrne; Andrew M Rogers; Shaikh Gholam Wahid; Christian M Burns; Gavin Lotay; D. T Doherty; Jack Henderson; Connor O'Shea; Greg Willmott; Chris Cousins; Dan W Bardayan; Scott R Carmichael; Maike Beuschlein; Dirk Rudolph; Claus Müller-Gatermann; Michael P Carpenter; Amel Korichi; Torben Lauritsen; Walter Reviol; Darek Seweryniak; Marco Siciliano; Aysegul Ertoprak; Vasil Karayonchev; Eilens L Lopez Saavedra; Nirupama Sensharma; Casper-David Lakenbrink; Ragandeep Singh Sidhu; Yuliia Hrabar; Luis Sarmiento; Yiyi Zhu; Kartikeya Sharma; Jacob Heery; Reuben Russell

Investigation of the <sup>57</sup>Ni(p,γ)<sup>58</sup>Cu reaction in the νp process

ORAL

Abstract

In astrophysical environments containing both a strong antineutrino flux and neutron-deficient nuclei, the vp process can modify the nucleosynthesis pathway and the ejecta composition. In these environments protons interact with antineutrinos, converting them into free neutrons.These neutrons are then available to undergo neutron-capture reactions on neutron-deficient isotopes present in the system, pushing the composition towards stability. Several (n,p) and (p,γ) reactions have been identified that influence the vp process where the ⁵⁷Ni(p,γ)⁵⁸Cu reaction was found to significantly impact uncertainties in the astrophysical models. While the level structure of ⁵⁸Cu (N=Z) has been studied in detail, many of the low-spin excited states above the proton separation energy that dominate the (p,γ) reaction rate, have relatively large uncertainties or have not been measured. We recently performed a high-resolution in-beam γγ-coincidence experiment using Gammasphere coupled to Neutron Shell to identify transitions from astrophysically important low-spin states in ⁵⁸Cu which were selectively populated via the ⁵⁸Ni(p,n) reaction using a 17-MeV proton beam at ATLAS. Preliminary results will be presented including several newly observed states above the proton separation energy.

^*This material is based upon work supported by the U.S. Department of Energy, Office of Science, Office of Nuclear Physics, under Award Number DE-FG02-94ER40848 (UML).

Oct. 10, 2024, 11:30 AM – Oct. 10, 2024, 11:42 AM

Presenters

Sean Patrick Byrne
- University of Massachusetts Lowell

Authors

Sean Patrick Byrne
- University of Massachusetts Lowell
Andrew M Rogers
- University of Massachusetts Lowell
- University of Massachusetts-Lowell
Shaikh Gholam Wahid
- University of Massachusetts Lowell
Christian M Burns
- University of Massachusetts Lowell
Gavin Lotay
- University of Surrey
D. T Doherty
- University of Surrey
Jack Henderson
- University of Surrey
Connor O'Shea
- University of Surrey
Greg Willmott
- University of Surrey
Chris Cousins
- University of Surrey
Dan W Bardayan
- University of Notre Dame
Scott R Carmichael
- University of Notre Dame
Maike Beuschlein
- TU Darmstadt
Dirk Rudolph
- Lund University
Claus Müller-Gatermann
- Argonne National Laboratory
Michael P Carpenter
- Argonne National Laboratory
Amel Korichi
- Argonne National Laboratory/Université d'Orsay
Torben Lauritsen
- Argonne National Laboratory
Walter Reviol
- Argonne National Laboratory
Darek Seweryniak
- Argonne National Laboratory
Marco Siciliano
- Argonne National Laboratory
Aysegul Ertoprak
- Argonne National Laboratory
Vasil Karayonchev
- Argonne National Laboratory
Eilens L Lopez Saavedra
- Argonne National Laboratory
Nirupama Sensharma
- Argonne National Laboratory
Casper-David Lakenbrink
- Argonne National Laboratory/University of Cologne
Ragandeep Singh Sidhu
- The University of Edinburgh
Yuliia Hrabar
- Lund University
Luis Sarmiento
- LUND University
Yiyi Zhu
- UNIVERSITY OF MASSACHUSETTS Lowell
- University of Massachusetts Lowell
Kartikeya Sharma
- University of Massachusetts Lowell
Jacob Heery
- University of Surrey
Reuben Russell
- University of Surrey