# How does feedback affect the star formation histories of galaxies?

**Authors:** Kartheik G. Iyer, Tjitske K. Starkenburg, Greg L. Bryan, Rachel S. Somerville, Juan Pablo Alfonzo, Daniel Angl\'es-Alc\'azar, Suchetha Cooray, Romeel Dav\'e, Austen Gabrielpillai, Shy Genel, Sultan Hassan, Lars Hernquist, Christian Kragh Jespersen, Christopher C. Lovell, Boon Kiat Oh, Camilla Pacifici, Lucia A. Perez, Laura Sommovigo, Joshua S. Speagle, Sandro Tacchella, Megan T. Tillman, Francisco Villaescusa-Navarro, John F. Wu

arXiv: 2508.21152 · 2025-09-01

## TL;DR

This study uses cosmological simulations to analyze how different feedback processes influence galaxy star formation histories, revealing their complex interactions and potential as probes for cosmology and galaxy evolution.

## Contribution

It introduces a unified framework describing galaxy SFHs across multiple models, highlighting feedback's role and interactions in shaping star formation over cosmic time.

## Key findings

- Galaxy SFHs are sensitive to stellar feedback variations.
- Interactions between stellar and AGN feedback regulate gas availability.
- A general set of equations links SFH shape to physical galaxy properties.

## Abstract

Star formation in galaxies is regulated by the interplay of a range of processes that shape the multiphase gas in the interstellar and circumgalactic media. Using the CAMELS suite of cosmological simulations, we study the effects of varying feedback and cosmology on the average star formation histories (SFHs) of galaxies at $z\sim0$ across the IllustrisTNG, SIMBA and ASTRID galaxy formation models. We find that galaxy SFHs in all three models are sensitive to changes in stellar feedback, which affects the efficiency of baryon cycling and the rates at which central black holes grow, while effects of varying AGN feedback depend on model-dependent implementations of black hole seeding, accretion and feedback. We also find strong interaction terms that couple stellar and AGN feedback, usually by regulating the amount of gas available for the central black hole to accrete. Using a double power-law to describe the average SFHs, we derive a general set of equations relating the shape of the SFHs to physical quantities like baryon fraction and black hole mass across all three models. We find that a single set of equations (albeit with different coefficients) can describe the SFHs across all three CAMELS models, with cosmology dominating the SFH at early times, followed by halo accretion, and feedback and baryon cycling at late times. Galaxy SFHs provide a novel, complementary probe to constrain cosmology and feedback, and can connect the observational constraints from current and upcoming galaxy surveys with the physical mechanisms responsible for regulating galaxy growth and quenching.

## Full text

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## Figures

81 figures with captions in the complete paper: https://tomesphere.com/paper/2508.21152/full.md

## References

169 references — full list in the complete paper: https://tomesphere.com/paper/2508.21152/full.md

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Source: https://tomesphere.com/paper/2508.21152