The role of low-lying resonances for 10Be(p,α) reaction rate and implications for the formation of the Solar System

Abstract

Evidence for the presence of short-lived radioactive isotopes when the Solar System formed is preserved in meteorites, providing insights into the conditions at the birth of our Sun. A low-mass core-collapse supernova had been postulated as a candidate for the origin of 10Be, reinforcing the idea that a supernova triggered the formation of the Solar System. We present a detailed study of the production of 10Be by the process in supernovae, which is very sensitive to the reaction rate of the major destruction channel, 10Be(p,α)7Li. With data from recent nuclear experiments that show the presence of a resonant state in 11B at ≈~193 keV, we derive new values for the 10Be(p,α)7Li reaction rate which are significantly higher than previous estimates. We show that, with the new 10Be(p,α)7Li reaction rate, a low mass CCSN is unlikely to produce enough 10Be to explain the observed 10Be/ 9Be ratio in meteorites, even for a wide range of neutrino spectra considered in our models. These findings point towards spallation reactions induced by solar energetic particles in the early Solar System as the origin of 10Be.