Two Modes of LyC Escape From Bursty Star Formation: Implications for [C II] Deficits and the Sources of Reionization

TL;DR

This study uses cosmological simulations to identify two distinct modes of Lyman Continuum photon escape from galaxies, linking their properties to observable signatures like [CII] deficits, and discusses their roles in cosmic reionization.

Contribution

It introduces a classification of LyC leakers into Bursty and Remnant types based on star formation history and links their properties to observable signatures, advancing understanding of reionization sources.

Findings

Bursty Leakers have high ionization parameters and high SFR bursts.

Remnant Leakers exhibit properties of density-bounded nebulae.

Both types show [CII] deficits, with different dependencies on SFR measures.

Abstract

We use the SPHINX$^{20}$ cosmological radiation hydrodynamics simulation to study how Lyman Continuum (LyC) photons escape from galaxies and the observational signatures of this escape. We define two classes of LyC leaker: Bursty Leakers and Remnant Leakers, based on their star formation rates (SFRs) that are averaged over 10 Myr (SFR$_{10}$) or 100 Myr (SFR$_{100}$). Both have $f_{\rm esc}>20\%$ and experienced an extreme burst of star formation, but Bursty Leakers have ${\rm SFR_{10}>SFR_{100}}$, while Remnant Leakers have ${\rm SFR_{10}<SFR_{100}}$. The maximum SFRs in these bursts were typically $\sim100$ times greater than the SFR of the galaxy prior to the burst, a rare $2\sigma$ outlier among the general high-redshift galaxy population. Bursty Leakers are qualitatively similar to ionization-bounded nebulae with holes, exhibiting high ionization parameters and typical HII region gas densities. Remnant Leakers show properties of density-bounded nebulae, having normal ionization parameters but much lower HII region densities. Both types of leaker exhibit [CII]$_{\rm 158\mu m}$ deficits on the [CII]-SFR$_{100}$ relation, while only Bursty Leakers show deficits when SFR$_{10}$ is used. We predict that [CII] luminosity and SFR indicators such as H$\alpha$ and M$_{\rm 1500\r{A}}$ can be combined to identify both types of LyC leaker and the mode by which photons are escaping. These predictions can be tested with [CII] observations of known $z=3-4$ LyC leakers. Finally, we show that leakers with $f_{\rm esc}>20\%$ dominate the ionizing photon budget at $z\gtrsim7.5$ but the contribution from galaxies with $f_{\rm esc}<5\%$ becomes significant at the tail-end of reionization.