First direct measurement of 59Cu(p,α)56Ni: A step towards constraining the Ni-Cu cycle in the Cosmos

Abstract

Reactions on the proton-rich nuclides drive the nucleosynthesis in Core-Collapse Supernovae (CCSNe) and in X-ray bursts (XRBs). CCSNe eject the nucleosynthesis products to the interstellar medium and hence are a potential inventory of p-nuclei, whereas in XRBs nucleosynthesis powers the light curves. In both astrophysical sites the Ni-Cu cycle, which features a competition between 59Cu(p,α)56Ni and 59Cu(p,γ)60Zn, could potentially halt the production of heavier elements. Here, we report the first direct measurement of 59Cu(p,α)56Ni using a re-accelerated 59Cu beam and cryogenic solid hydrogen target. Our results show that the reaction proceeds predominantly to the ground state of 56Ni and the experimental rate has been found to be lower than Hauser-Feshbach-based statistical predictions. New results hint that the p-process could operate at higher temperatures than previously inferred and therefore remains a viable site for synthesizing the heavier elements.