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Main Authors: McCaffrey, Joe, Hardin, Samantha, Wise, John H., Regan, John A.
Format: Preprint
Published: 2025
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Online Access:https://arxiv.org/abs/2509.07695
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author McCaffrey, Joe
Hardin, Samantha
Wise, John H.
Regan, John A.
author_facet McCaffrey, Joe
Hardin, Samantha
Wise, John H.
Regan, John A.
contents JWST has identified some of the Universe's earliest galaxies, repeatedly pushing the frontier to ever higher redshifts and stellar masses. The presence of such extreme galaxies at such early times, with large stellar populations and high star-formation rates, naturally results in a tension between observation and theory. This tension between numerical models and observations can be either due to our underlying cosmological models or due to a gap in our understanding of early Universe astrophysics. In a prelude to this letter, we showed how the Renaissance simulations, which focused on high redshift galaxy formation were able to reconstruct similar stellar masses to the earliest and highest mass galaxies that had been discovered by JWST at the time of its publication (McCaffrey et al.2023). Since then many more galaxies have been discovered by JWST, in particular the "Mirage-or-Miracle" (MoM) survey broke the record recently with the highest redshift galaxy MoM-z14, which has a spectroscopically confirmed redshift of $z \sim 14.44$ followed closely by GS-z14 with a spectroscopically confirmed redshift of $z \sim 14.3$. We investigate in this letter whether these newly discovered galaxies are in conflict with the Renaissance simulations and thus whether they are causing tension with our established models of cosmology and/or high-redshift astrophysics. We discover that MoM-z14's high mass at early redshift can be explained by the Renaissance simulation suite, whereas the extremely high stellar mass of GS-z14 remains an outlier when compared to previous measurements of high-redshift galaxies detected by JWST and our numerical models (even after accounting for cosmic variance).
format Preprint
id arxiv_https___arxiv_org_abs_2509_07695
institution arXiv
publishDate 2025
record_format arxiv
spellingShingle Beyond No Tension: JWST z > 10 Galaxies Push Simulations to the Limit
McCaffrey, Joe
Hardin, Samantha
Wise, John H.
Regan, John A.
Astrophysics of Galaxies
JWST has identified some of the Universe's earliest galaxies, repeatedly pushing the frontier to ever higher redshifts and stellar masses. The presence of such extreme galaxies at such early times, with large stellar populations and high star-formation rates, naturally results in a tension between observation and theory. This tension between numerical models and observations can be either due to our underlying cosmological models or due to a gap in our understanding of early Universe astrophysics. In a prelude to this letter, we showed how the Renaissance simulations, which focused on high redshift galaxy formation were able to reconstruct similar stellar masses to the earliest and highest mass galaxies that had been discovered by JWST at the time of its publication (McCaffrey et al.2023). Since then many more galaxies have been discovered by JWST, in particular the "Mirage-or-Miracle" (MoM) survey broke the record recently with the highest redshift galaxy MoM-z14, which has a spectroscopically confirmed redshift of $z \sim 14.44$ followed closely by GS-z14 with a spectroscopically confirmed redshift of $z \sim 14.3$. We investigate in this letter whether these newly discovered galaxies are in conflict with the Renaissance simulations and thus whether they are causing tension with our established models of cosmology and/or high-redshift astrophysics. We discover that MoM-z14's high mass at early redshift can be explained by the Renaissance simulation suite, whereas the extremely high stellar mass of GS-z14 remains an outlier when compared to previous measurements of high-redshift galaxies detected by JWST and our numerical models (even after accounting for cosmic variance).
title Beyond No Tension: JWST z > 10 Galaxies Push Simulations to the Limit
topic Astrophysics of Galaxies
url https://arxiv.org/abs/2509.07695