# Forming early-type galaxies without AGN feedback: a combination of   merger-driven outflows and inefficient star formation

**Authors:** Michael Kretschmer, Romain Teyssier

arXiv: 1906.11836 · 2021-02-17

## TL;DR

This paper presents a new simulation model for galaxy formation that combines merger-driven outflows and inefficient star formation, successfully forming early-type galaxies without AGN feedback and matching observed star formation properties.

## Contribution

The study introduces a detailed subgrid model for supernova feedback and star formation based on turbulence, applied in cosmological simulations to form early-type galaxies without AGN feedback.

## Key findings

- Regulation of stellar and baryonic content by feedback mechanisms.
- High-redshift merger induces starburst with ~10% efficiency.
- Late-time galaxy becomes quiescent with <1% efficiency.

## Abstract

Regulating the available gas mass inside galaxies proceeds through a delicate balance between inflows and outflows, but also through the internal depletion of gas due to star formation. At the same time, stellar feedback is the internal engine that powers the strong outflows. Since star formation and stellar feedback are both small scale phenomena, we need a realistic and predictive subgrid model for both. We describe the implementation of supernova momentum feedback and star formation based on the turbulence of the gas in the RAMSES code. For star formation, we adopt the so-called multi-freefall model. The resulting star formation efficiencies can be significantly smaller or bigger than the traditionally chosen value of $1\%$. We apply these new numerical models to a prototype cosmological simulation of a massive halo that features a major merger which results in the formation of an early-type galaxy without using AGN feedback. We find that the feedback model provides the first order mechanism for regulating the stellar and baryonic content in our simulated galaxy. At high redshift, the merger event pushes gas to large densities and large turbulent velocity dispersions, such that efficiencies come close to $10\%$, resulting in large SFR. We find small molecular gas depletion time during the starburst, in perfect agreement with observations. Furthermore, at late times, the galaxy becomes quiescent with efficiencies significantly smaller than $1\%$, resulting in small SFR and long molecular gas depletion time.

## Full text

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## Figures

12 figures with captions in the complete paper: https://tomesphere.com/paper/1906.11836/full.md

## References

105 references — full list in the complete paper: https://tomesphere.com/paper/1906.11836/full.md

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Source: https://tomesphere.com/paper/1906.11836