Spatially resolved [CII]-gas conversion factor in early galaxies

Abstract

Determining how efficiently gas collapses into stars at high-redshift is key to understanding galaxy evolution in the Epoch of Reionization (EoR). Globally, this process is quantified by the gas depletion time (tdep); on resolved scales, by the slope and normalization of the Kennicutt-Schmidt (KS) relation. This work explores the global (α[CII]) and spatially resolved (W[CII]) [CII]-to-gas conversion factors at high-z and their role in inferring reliable gas masses, surface densities, and tdep in the EoR. We select galaxies at 4<z<9 from the SERRA cosmological zoom-in simulation, that features on-the-fly radiative transfer and resolves interstellar medium properties down to ≈30 pc. The [CII] emission modelling from photodissociation regions allow us to derive global α [CII], and maps of W[CII]. We study their dependence on gas metallicity (Z), density (n), Mach number (M), and burstiness parameter (ks), and provide best fit relations. The α[CII] decreases with increasing Z and galaxy compactness, while the resolved W[CII] shows two regimes: at Z< 0.2 Z, it anticorrelates with n and Z, but not with ks; above this threshold, it also depends on ks, with more bursty regions showing lower conversion factors. This implies W[CII] [CII]-0.5, as dense, metal-rich, and bursty regions exhibit higher [CII] surface brightness. Applying a constant α[CII] overestimates gas in bright [CII] patches, thus flattening the KS slope and overestimating tdep by a factor of ≈4.

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