The recent discovery of Little Red Dots (LRDs) by the James Webb Space Telescope has challenged traditional models of early galaxy and black hole co-evolution. The nature of these highly compact objects remains heavily debated, with explanations divided between dust-reddened active galactic nuclei (AGN) and extremely dense stellar populations. We perform high-resolution cosmological simulations to model the formation of LRD precursors. Motivated by recent high-redshift observations and theoretical results, we specifically explore environments characterized by high star formation efficiencies (30\% and 100\%) and confined feedback. Our simulations naturally produce highly compact galaxies with stellar masses of 107−6×108 \,M ⊙ , with most of the mass concentrated within 200−300 pc. We find that, in these dense environments, gas inflows, gravitational torques, and stellar dynamical friction operate on highly efficient timescales. Over a 10 Myr timescale, gas inflows can accumulate ∼107M⊙ at the galactic center, while gravitational torques and dynamical friction can contribute an additional 105−109 \,M ⊙ and 103−104 \, M ⊙ through the inward migration of massive stars. Assuming a conservative 10\% efficiency to account for feedback, this rapid mass accumulation can lead to the formation of a ∼106 \,M ⊙ central black hole, naturally giving rise to an AGN in these dense systems. Therefore, stellar and AGN interpretations of LRDs may not be mutually exclusive; rather, dense stellar systems are likely precursors to AGN.
Little red dot progenitors from compact starbursts. A natural path to early AGN formation / Liempi, M., Latif, M.A., Schleicher, D.R.G.. - In: THE ASTROPHYSICAL JOURNAL. - ISSN 0004-637X. - 174:2(2026), pp. 1-12. [10.3847/1538-4357/ae7710]
Little red dot progenitors from compact starbursts. A natural path to early AGN formation
Matias Liempi;
2026
Abstract
The recent discovery of Little Red Dots (LRDs) by the James Webb Space Telescope has challenged traditional models of early galaxy and black hole co-evolution. The nature of these highly compact objects remains heavily debated, with explanations divided between dust-reddened active galactic nuclei (AGN) and extremely dense stellar populations. We perform high-resolution cosmological simulations to model the formation of LRD precursors. Motivated by recent high-redshift observations and theoretical results, we specifically explore environments characterized by high star formation efficiencies (30\% and 100\%) and confined feedback. Our simulations naturally produce highly compact galaxies with stellar masses of 107−6×108 \,M ⊙ , with most of the mass concentrated within 200−300 pc. We find that, in these dense environments, gas inflows, gravitational torques, and stellar dynamical friction operate on highly efficient timescales. Over a 10 Myr timescale, gas inflows can accumulate ∼107M⊙ at the galactic center, while gravitational torques and dynamical friction can contribute an additional 105−109 \,M ⊙ and 103−104 \, M ⊙ through the inward migration of massive stars. Assuming a conservative 10\% efficiency to account for feedback, this rapid mass accumulation can lead to the formation of a ∼106 \,M ⊙ central black hole, naturally giving rise to an AGN in these dense systems. Therefore, stellar and AGN interpretations of LRDs may not be mutually exclusive; rather, dense stellar systems are likely precursors to AGN.| File | Dimensione | Formato | |
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