2024
DOI: 10.3847/1538-4357/ad0a98
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Galaxy Quenching at the High Redshift Frontier: A Fundamental Test of Cosmological Models in the Early Universe with JWST-CEERS

Asa F. L. Bluck,
Christopher J. Conselice,
Katherine Ormerod
et al.

Abstract: We present an analysis of the quenching of star formation in massive galaxies (M * > 109.5 M ⊙) within the first 0.5–3 Gyr of the Universe’s history utilizing JWST-CEERS data. We utilize a combination of advanced statistical methods to accurately constrain the intrinsic dependence of quenching in a multidimensional and intercorrelated parameter space. Specifically, we apply random forest classification, area statistics, and a partial correlation analysis… Show more

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Cited by 12 publications
(3 citation statements)
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“…The basis of our model is that the black hole mass is the primary parameter that controls high-z star formation quenching. This premise is supported by recent analyses of JWST/ CEERS data with cosmological simulations (IllustrisTNG and EAGLE), showing that high-z galaxy quenching is primarily regulated by the mass of the SMBH (Piotrowska et al 2022;Bluck et al 2024). Previous cosmological simulations already showed that star formation quenching should scale with energy input from the central SMBH over the entire lifetime of the galaxy, which is proportional to the black hole mass (Terrazas et al 2020;Bluck et al 2024).…”
Section: Model Principlesmentioning
confidence: 57%
See 1 more Smart Citation
“…The basis of our model is that the black hole mass is the primary parameter that controls high-z star formation quenching. This premise is supported by recent analyses of JWST/ CEERS data with cosmological simulations (IllustrisTNG and EAGLE), showing that high-z galaxy quenching is primarily regulated by the mass of the SMBH (Piotrowska et al 2022;Bluck et al 2024). Previous cosmological simulations already showed that star formation quenching should scale with energy input from the central SMBH over the entire lifetime of the galaxy, which is proportional to the black hole mass (Terrazas et al 2020;Bluck et al 2024).…”
Section: Model Principlesmentioning
confidence: 57%
“…Understanding the high-redshift evolution of the scaling relations is fundamental for two reasons. First, it informs us about the physical processes that regulate the growth of the black hole and stellar component (see, e.g., Vogelsberger et al 2014;Schaye et al 2015;Weinberger et al 2017;Nelson et al 2018;Terrazas et al 2020;Piotrowska et al 2022;Bluck et al 2024). Second, it may inform us of the seeding mechanism that formed the central black hole in the first place.…”
Section: Discussionmentioning
confidence: 99%
“…Additionally, the observational measurements should be intended as lower limits and can be significantly affected by selection, obscuration (Hickox & Alexander 2018). We also note that there have been many recent studies reporting discoveries of quenched galaxies hosting AGN (Ito et al 2022;Carnall et al 2023a;Bluck et al 2024), as well as several cases where AGN emission is absent (Jin et al 2024;Nanayakkara et al 2024), leaving this issue under debate.…”
Section: Quenching Mechanismsmentioning
confidence: 97%