Investigation of 31P levels near the proton threshold by Nuclear Resonance Fluorescence and the impact on the 30Si(p,γ)31P thermonuclear rate

Abstract

We investigated the nuclear structure of 31P near the proton threshold using Nuclear Resonance Fluorescence (NRF) to refine the properties of key resonances in the 30Si(p,γ)31P reaction, which is critical for nucleosynthesis in stellar environments. Excitation energies and spin-parities were determined for several states, including two unobserved resonances at Er = 18.7~keV and Er = 50.5~keV. The angular correlation analysis enabled the first unambiguous determination of the orbital angular momentum transfer for these states. These results provide a significant update to the 30Si(p,γ)31P thermonuclear reaction rate, with direct implications for models of nucleosynthesis in globular clusters and other astrophysical sites. The revised rate is substantially lower than previous estimates at temperatures below 200~MK, affecting predictions for silicon isotopic abundances in stellar environments. Our work demonstrates the power of NRF in constraining nuclear properties, and provides a framework for future studies of low-energy resonances relevant to astrophysical reaction rates.