Measurement of $^{19}$F($p$,$\gamma$)$^{20}$Ne reaction suggests CNO break-out in first stars

TL;DR

This study measures a key nuclear reaction at unprecedented low energies, revealing a higher reaction rate that suggests a new pathway for calcium production in the first stars, impacting our understanding of early stellar evolution.

Contribution

The paper provides the first direct measurement of the $^{19}$F($p$,$ extgamma$)$^{20}$Ne reaction rate at low energies, indicating a significant increase in the rate relevant to Pop III star nucleosynthesis.

Findings

Discovery of a key resonance at 225 keV.

Reaction rate up to 7.4 times higher than previous estimates.

Implications for calcium production in first stars.

Abstract

The origin of calcium production in the first stars (Pop III stars), which formed out of the primordial matter of the Big Bang, and their fates, remain most fascinating mysteries in astrophysics. Advanced nuclear burning and supernovae were thought to be the dominant source of the Ca production seen in all stars. Here we report on a qualitatively different path to Ca production through break-out from the "warm" carbon-nitrogen-oxygen (CNO) cycle. We extend direct measurement of the $^{19}$F($p$, $\gamma$)$^{20}$Ne break-out reaction down to an unprecedentedly low energy point of 186 keV and discover a key resonance at 225 keV. In the domain of astrophysical interest, at around 0.1 giga kelvin, this thermonuclear $^{19}$F($p$,$\gamma$)$^{20}$Ne rate is up to a factor of 7.4 larger than the previous recommended rate. Our stellar models show a stronger break-out during stellar hydrogen burning than thought before, and may reveal the nature of Ca production in Pop III stars imprinted on the oldest known ultra-iron poor star, SMSS0313-6708. This result from the China Jinping Underground Laboratory, the deepest laboratory in the world, offering an environment with extremely low cosmic-ray induced background, has far-reaching implications on our understanding of how the first stars evolve and die. Our rate showcases the impact that faint Pop III star supernovae can have on the nucleosynthesis observed in the oldest known stars and first galaxies, key mission targets of the James Webb Space Telescope.