http://arxiv.org/abs/2210.15699
Given their extremely faint apparent brightness, the nature of the first galaxies and how they reionized the Universe’s gas are not yet understood. Here we report the discovery, in James Webb Space Telescope (JWST) imaging, of a highly magnified, low-mass (log(M_*/M_sol)=7.70^{+0.11}_{-0.09}) galaxy visible when the Universe was only 510 Myr old, and follow-up prism spectroscopy of the galaxy extending from Lyman alpha to [O III] 5007 in its rest frame. Our JWST spectrum provides [O III] 5007 and H beta detections with a respective signal-to-noise ratio (S/N) of 33 and 7, as well as four additional lines with S/N > 2. These emission lines yield a redshift of z=9.51 and star-formation rate of 0.26^{+0.07}_{-0.05} M_sol per year. The galaxy’s large inferred value of [O III]/[O II] = 16 +- 6 suggests that this galaxy has an escape fraction of ionizing radiation larger than 10%, indicating that a population of similar objects could contribute substantially to the reionization budget. Using multiple techniques, we infer a gas oxygen abundance of 12 + log(O/H) = 7.47 +- 0.10 dex, consistent within 2 sigma of the mass-metallicity relation observed for dwarf galaxies in the local Universe.
H. Williams, P. Kelly, W. Chen, et. al.
Mon, 31 Oct 22
25/60
Comments: N/A