High-z [OI] emission lines: ColdSIM simulations and ALMA observations
Abstract
Neutral-oxygen [OI] far-infrared emission lines at 63μm and 145μm are powerful probes of the physical conditions in the interstellar medium, although they have not been fully exploited in high-redshift studies. We investigate the connection between [OI] emission lines and key galaxy properties, such as star formation rate (SFR) and H2 content. Our predictions are compared with existing observations and new data analysed in this work. We post-process the outputs of the ColdSIM cosmological simulations with the DESPOTIC model, taking into account [OI]63μm self-absorption by cold foreground material. A Random Forest algorithm is employed to accelerate computations and new observational ALMA data for galaxies at redshift z 5-7 are used to validate our model. Our predictions show significant [OI]63μm luminosities (≈ 108\, L) for galaxies with SFRs of ≈ 102\, M\, yr-1. The 145μm line luminosity is typically 15 \% the [OI]63μm one and is a factor ≈ 2-20 below high-z observations. Both [OI] lines correlate with SFR and molecular mass, but exhibit flattening in scaling relations with metallicity and stellar mass. Foreground self-absorption reduces the [OI] flux by a factor of 2-4, consistent with empirical corrections in observational studies. We find typical line ratios of [OI]63μm / [CII]158μm ≈ 1 and [OI]145μm / [CII]158μm ≈ 0.2 \, - consistent with z 6 observations, but only when [OI]63μm self-absorption is included. Both [OI]63μm and [OI]145μm lines serve as tracers of star formation and molecular gas at high redshift. Their joint detection can provide constraints on the properties of the early interstellar medium and self-absorption of the [OI]63μm line.
Turn this paper into a full lesson
ArcXiv compiles a staged curriculum from this paper: 8-12 lessons across beginner → advanced, synthesised section guides, visuals, flashcards, a quiz, exercises, and on-demand deep dives per section. Grounded in the abstract, never invented.