# Forming disc galaxies in major mergers: III. The effect of angular   momentum on the radial density profiles of disc galaxies

**Authors:** N. Peschken, E. Athanassoula, S. A. Rodionov

arXiv: 1703.00916 · 2017-03-06

## TL;DR

This study investigates how angular momentum influences the radial density profiles of disc galaxies formed in major mergers, revealing that higher angular momentum leads to larger disc scalelengths and break radii, with implications for stellar migration.

## Contribution

It demonstrates the correlation between initial angular momentum and disc density profile features in merger remnants and isolated galaxies, highlighting the role of angular momentum in galaxy structure formation.

## Key findings

- Higher angular momentum correlates with larger disc scalelengths.
- Angular momentum is acquired through accretion from gaseous halos.
- Outer disc stars mainly migrate inward over time.

## Abstract

We study the effect of angular momentum on the surface density profiles of disc galaxies, using high resolution simulations of major mergers whose remnants have downbending radial density profiles (type II). As described in the previous papers of this series, in this scenario, most of the disc mass is acquired after the collision via accretion from a hot gaseous halo. We find that the inner and outer disc scalelengths, as well as the break radius, correlate with the total angular momentum of the initial merging system, and are larger for high angular momentum systems. We follow the angular momentum redistribution in our simulated galaxies, and find that, like the mass, the disc angular momentum is acquired via accretion, i.e. to the detriment of the gaseous halo. Furthermore, high angular momentum systems give more angular momentum to their discs, which affects directly their radial density profile. Adding simulations of isolated galaxies to our sample, we find that the correlations are valid also for disc galaxies evolved in isolation. We show that the outer part of the disc at the end of the simulation is populated mainly by inside-out stellar migration, and that in galaxies with higher angular momentum, stars travel radially further out. This, however, does not mean that outer disc stars (in type II discs) were mostly born in the inner disc. Indeed, generally the break radius increases over time, and not taking this into account leads to overestimating the number of stars born in the inner disc.

## Full text

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## Figures

29 figures with captions in the complete paper: https://tomesphere.com/paper/1703.00916/full.md

## References

45 references — full list in the complete paper: https://tomesphere.com/paper/1703.00916/full.md

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Source: https://tomesphere.com/paper/1703.00916