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Main Authors: Lu, Shengdong, Frenk, Carlos S., Lacey, Cedric G., Gebek, Andrea, Schaye, Joop, Cole, Shaun, Bose, Sownak, Durrant, Anna, Andreadis, Nick, Baes, Maarten, Benítez-Llambay, Alejandro, Chaikin, Evgenii, Correa, Camila, Crain, Robert A., Huško, Filip, McGibbon, Robert J., Ploeckinger, Sylvia, Richings, Alexander J., Schaller, Matthieu, Trayford, James W.
Format: Preprint
Published: 2026
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Online Access:https://arxiv.org/abs/2605.06782
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author Lu, Shengdong
Frenk, Carlos S.
Lacey, Cedric G.
Gebek, Andrea
Schaye, Joop
Cole, Shaun
Bose, Sownak
Durrant, Anna
Andreadis, Nick
Baes, Maarten
Benítez-Llambay, Alejandro
Chaikin, Evgenii
Correa, Camila
Crain, Robert A.
Huško, Filip
McGibbon, Robert J.
Ploeckinger, Sylvia
Richings, Alexander J.
Schaller, Matthieu
Trayford, James W.
author_facet Lu, Shengdong
Frenk, Carlos S.
Lacey, Cedric G.
Gebek, Andrea
Schaye, Joop
Cole, Shaun
Bose, Sownak
Durrant, Anna
Andreadis, Nick
Baes, Maarten
Benítez-Llambay, Alejandro
Chaikin, Evgenii
Correa, Camila
Crain, Robert A.
Huško, Filip
McGibbon, Robert J.
Ploeckinger, Sylvia
Richings, Alexander J.
Schaller, Matthieu
Trayford, James W.
contents JWST has enabled the detection of galaxies in the earliest stages of cosmic history. We compare the ultraviolet luminosity functions (UVLFs) at redshifts $z=7-15$ predicted by the new cosmological hydrodynamics simulations, COLIBRE with observations, including those from JWST. The UV luminosities of COLIBRE galaxies are derived using the radiative transfer code SKIRT, which tracks stellar emission and its processing through the multi-phase interstellar medium and dust distribution predicted by COLIBRE. We find that although COLIBRE is consistent with the observed evolution of the stellar mass function up to $z=12$, its dust-attenuated UVLFs fall systematically below the observations at the bright end: at the number density of $10^{-6}\,\mathrm{Mpc^{-3}\,mag^{-1}}$, the brightest galaxies are underluminous by $\approx 1\,\rm mag$ at $z=7$, increasing to $\approx 2.5\,\rm mag$ at $z=15$. Accounting for observational uncertainties brings the COLIBRE UVLFs closer to the observational data, but does not fully resolve the discrepancy. Ignoring dust attenuation allows COLIBRE to produce sufficiently bright galaxies at $7\lesssim z \lesssim 12$, while at $z=15$, COLIBRE still underpredicts the luminosities of the brightest galaxies, indicating the need for additional physical mechanisms to boost the UV luminosities at the earliest cosmic epochs, such as a ''top-heavy'' stellar initial mass function. We fit the COLIBRE UVLFs with Schechter functions and calculate the evolution of the best-fit parameters. We find that the galaxy number density decreases, the characteristic luminosity becomes fainter and the faint-end slope becomes steeper towards higher redshifts. The UV luminosity density decreases by a factor of $\approx 300$ from $z = 7$ to $z = 15$.
format Preprint
id arxiv_https___arxiv_org_abs_2605_06782
institution arXiv
publishDate 2026
record_format arxiv
spellingShingle The galaxy ultraviolet luminosity function from $z=7$ to $15$ in the COLIBRE simulations
Lu, Shengdong
Frenk, Carlos S.
Lacey, Cedric G.
Gebek, Andrea
Schaye, Joop
Cole, Shaun
Bose, Sownak
Durrant, Anna
Andreadis, Nick
Baes, Maarten
Benítez-Llambay, Alejandro
Chaikin, Evgenii
Correa, Camila
Crain, Robert A.
Huško, Filip
McGibbon, Robert J.
Ploeckinger, Sylvia
Richings, Alexander J.
Schaller, Matthieu
Trayford, James W.
Astrophysics of Galaxies
JWST has enabled the detection of galaxies in the earliest stages of cosmic history. We compare the ultraviolet luminosity functions (UVLFs) at redshifts $z=7-15$ predicted by the new cosmological hydrodynamics simulations, COLIBRE with observations, including those from JWST. The UV luminosities of COLIBRE galaxies are derived using the radiative transfer code SKIRT, which tracks stellar emission and its processing through the multi-phase interstellar medium and dust distribution predicted by COLIBRE. We find that although COLIBRE is consistent with the observed evolution of the stellar mass function up to $z=12$, its dust-attenuated UVLFs fall systematically below the observations at the bright end: at the number density of $10^{-6}\,\mathrm{Mpc^{-3}\,mag^{-1}}$, the brightest galaxies are underluminous by $\approx 1\,\rm mag$ at $z=7$, increasing to $\approx 2.5\,\rm mag$ at $z=15$. Accounting for observational uncertainties brings the COLIBRE UVLFs closer to the observational data, but does not fully resolve the discrepancy. Ignoring dust attenuation allows COLIBRE to produce sufficiently bright galaxies at $7\lesssim z \lesssim 12$, while at $z=15$, COLIBRE still underpredicts the luminosities of the brightest galaxies, indicating the need for additional physical mechanisms to boost the UV luminosities at the earliest cosmic epochs, such as a ''top-heavy'' stellar initial mass function. We fit the COLIBRE UVLFs with Schechter functions and calculate the evolution of the best-fit parameters. We find that the galaxy number density decreases, the characteristic luminosity becomes fainter and the faint-end slope becomes steeper towards higher redshifts. The UV luminosity density decreases by a factor of $\approx 300$ from $z = 7$ to $z = 15$.
title The galaxy ultraviolet luminosity function from $z=7$ to $15$ in the COLIBRE simulations
topic Astrophysics of Galaxies
url https://arxiv.org/abs/2605.06782