First direct carbon abundance measured at $z>10$ in the lensed galaxy MACS0647$-$JD

TL;DR

This study reports the first direct measurement of carbon-to-oxygen ratio in a galaxy at redshift greater than 10, providing insights into early universe chemical enrichment and star formation processes.

Contribution

It presents the first direct C/O abundance measurement at z>10, revealing higher-than-expected ratios and suggesting rapid star formation or unusual stellar populations in the early universe.

Findings

C/O ratio is sub-solar at -0.44

Higher than other high-z galaxies with C/O measurements

Potential implications for early star formation and stellar populations

Abstract

Investigating the metal enrichment in the early universe helps us constrain theories about the first stars and study the ages of galaxies. The lensed galaxy MACS0647$-$JD at $z=10.17$ is the brightest galaxy known at $z > 10$. Previous work analyzing JWST NIRSpec and MIRI data yielded a direct metallicity $\rm{12+log(O/H)}=7.79\pm0.09$ ($\sim$ 0.13 $Z_\odot$) and electron density $\rm{log}(n_e / \rm{cm^{-3}}) = 2.9 \pm 0.5$, the most distant such measurements to date. Here we estimate the direct C/O abundance for the first time at $z > 10$, finding a sub-solar ${\rm log(C/O)}=-0.44^{+0.06}_{-0.07}$. This is higher than other $z>6$ galaxies with direct C/O measurements, likely due to higher metallicity. It is also slightly higher than galaxies in the local universe with similar metallicity. This may suggest a very efficient and rapid burst of star formation, a low effective oxygen abundance yield, or the presence of unusual stellar populations including supermassive stars. Alternatively, the strong CIII]${\rm {\lambda}{\lambda}}$1907,1909 emission ($14\pm 3\,{\r{A}}$ rest-frame EW) may originate from just one of the two component star clusters JDB ($r \sim 20$ pc). Future NIRSpec IFU spectroscopic observations of MACS0647$-$JD will be promising for disentangling C/O in the two components to constrain the chemistry of individual star clusters just 460 Myr after the Big Bang.