JWST UNCOVER: The Overabundance of Ultraviolet-luminous Galaxies at $z>9$

TL;DR

This study uses JWST data to measure the UV luminosity function of galaxies at redshifts 9-12, revealing an overabundance of bright galaxies compared to models, with implications for galaxy formation theories.

Contribution

It provides the first robust UV luminosity function at z>9 accounting for lensing effects, showing a higher number of bright galaxies than predicted by existing models.

Findings

Bright galaxy density 10-100 times higher than models

Double power-law fits the bright end better than Schechter

Star formation rate density is 4-10 times higher than models

Abstract

Over the past year, JWST has uncovered galaxies at record-breaking distances up to $z \sim 13$. The JWST UNCOVER (ultra-deep NIRSpec and NIRcam observations before the epoch of reionization) program has obtained ultra-deep multiwavelength NIRCam imaging of the massive galaxy cluster Abell 2744 over $\sim 45$ arcmin$^{2}$ down to $\sim 29.5$ AB mag. Here, we present a robust ultraviolet (UV) luminosity function derived through lensing clusters at $9<z<12$. Using comprehensive end-to-end simulations, we account for all lensing effects and systematic uncertainties in deriving both the amplification factors and the effective survey volume. Our results confirm the intriguing excess of UV-bright galaxies ($M_{UV} < -20$ AB mag) previously reported at $z>9$ in recent JWST studies. In particular, a double power-law (DPL) describes better the bright-end of the luminosity function compared to the classical Schechter form. The number density of these bright galaxies is 10-100 times larger than theoretical predictions and previous findings based on Hubble Space Telescope (HST) observations. Additionally, we measure a star formation rate density of $\rho_{\rm SFR} = 10^{-2.64}$ M$_{\odot}$~yr$^{-1}$~Mpc$^{-3}$ at these redshifts, which is 4 to 10 times higher than galaxy formation models that assume a constant star formation efficiency. Future wide-area surveys and accurate modeling of lensing-assisted observations will reliably constrain both the bright and the dim end of the UV luminosity function at $z>9$, which will provide key benchmarks for galaxy formation models.