Evolution of the UV slope of galaxies at cosmic morning (z > 4): the properties of extremely blue galaxies

TL;DR

This study analyzes the UV continuum slopes of over 700 galaxies at high redshift, revealing that extremely blue galaxies have unique properties and potentially high Lyman continuum escape fractions, shedding light on early galaxy evolution.

Contribution

It provides the first detailed analysis of UV slopes for a large sample of high-redshift galaxies, identifying the physical properties of extremely blue galaxies and their implications for cosmic reionization.

Findings

Brighter galaxies have redder UV slopes, but this trend flattens at high redshift.

Extremely blue galaxies have lower dust, younger stars, and possibly high Lyman continuum escape fractions.

The UV slope evolution indicates steepening spectra with increasing redshift.

Abstract

We present an analysis of the UV continuum slope, beta, using a sample of 733 galaxies selected from a mixture of JWST ERS/GTO/GO observational programs and with z > 4. We consider spectroscopic data obtained with the low resolution PRISM/CLEAR NIRSpec configuration. Studying the correlation of beta with M_UV we find a decreasing trend of beta = (-0.056 +- 0.017) M_UV - (3.01 +- 0.34), consistent with brighter galaxies having redder beta as found in previous works. However, analysing the trend in separate redshift bins, we find that at high redshift the relation becomes much flatter, consistent with a flat slope. Furthermore, we find that beta decreases with redshift with an evolution as beta = (-0.075 +- 0.010) z - (1.496 +- 0.056), consistent with most previous results that show a steepening of the spectra going at higher z. We then select a sample of galaxies with extremely blue slopes (beta < -2.6): such slopes are steeper than what is predicted by stellar evolution models, even for dust free, young, metal poor populations, when the contribution of nebular emission is included. We select 51 extremely blue galaxies (XBGs) and we investigate the possible physical origin of their steep slopes, comparing them to a sub-sample of redder galaxies (matched in redshift and M_UV). We find that XBGs have younger stellar populations, stronger ionization fields, lower dust attenuation, and lower but not pristine metallicity (~ 10% solar) compared to red galaxies. However, these properties alone cannot explain the extreme beta values. By using indirect inference of Lyman continuum escape, using the most recent models, we estimate escape fractions f_esc > 10% in at least 25% of XBGs, while all the red sources have smaller f_esc. A reduced nebular continuum contribution as due to either a high escape fraction or to a bursty star-formation history is likely the origin of the extremely blue slopes.