Lyman Continuum Galaxy Candidates in COSMOS

TL;DR

This study uses deep HST imaging to identify candidate Lyman continuum galaxies at redshifts 3.7 to 4.4, aiming to constrain their properties and improve understanding of cosmic reionization, though more data is needed for definitive conclusions.

Contribution

The paper presents new candidate Lyman continuum galaxies at z~3.7-4.4 identified through HST imaging, expanding the sample for studying reionization sources.

Findings

Identified 3 spectroscopic LCG candidates at z~3.7-4.4.

Most likely escape fraction values are >100%, indicating measurement issues.

Further spectroscopic data needed for conclusive results.

Abstract

Star-forming galaxies are the sources likely to have reionized the universe. As we cannot observe them directly due to the opacity of the intergalactic medium at $z\gtrsim5$, we study $z\sim3\text{--}5$ galaxies as proxies to place observational constraints on cosmic reionization. Using new deep \textit{Hubble Space Telescope} rest-frame UV F336W and F435W imaging (30-orbit, $\sim40$~arcmin$^2$, $\sim29\text{--}30$~mag depth at 5$\sigma$), we attempt to identify a sample of Lyman continuum galaxies (LCGs). These are individual sources that emit ionizing flux below the Lyman break ($<912~\text{\AA}$). This population would allow us to constrain cosmic reionization parameters such as the number density and escape fraction ($f_{\rm esc}$) of ionizing sources. We compile a comprehensive parent sample that does not rely on the Lyman-break technique for redshifts. We present three new spectroscopic candidates at $z\sim3.7\text{--}4.4$, and 32 new photometric candidates. The high-resolution multi-band HST imaging and new Keck/Low Resolution Imaging Spectrometer (LRIS) redshifts make these promising spectroscopic LCG candidates. Using both a traditional and probabilistic approach, we find the most likely $f_{\rm esc}$ values for the three spectroscopic LCG candidates are $>100\%$, and therefore not physical. We are unable to confirm the true nature of these sources with the best available imaging and direct blue Keck/LRIS spectroscopy. More spectra, especially from the new class of 30 m telescopes, will be required to build a statistical sample of LCGs to place firm observational constraints on cosmic reionization.