# Angular Momentum of Early and Late Type Galaxies: Nature or Nurture?

**Authors:** Jingjing Shi, Andrea Lapi, Claudia Mancuso, Huiyuan Wang, Luigi Danese

arXiv: 1706.02165 · 2017-07-26

## TL;DR

This study explores the origins and evolution of angular momentum in early and late-type galaxies, revealing that intrinsic properties and mergers, rather than environment, primarily shape their angular momentum characteristics.

## Contribution

It introduces a model linking baryon infall, angular momentum retention, and galaxy type, highlighting the roles of biased collapse and mergers in galaxy evolution.

## Key findings

- Late-type galaxies have near-complete baryon infall and angular momentum retention.
- Early-type galaxies show reduced angular momentum due to mergers and biased collapse.
- Scatter in angular momentum relations is mainly due to dark matter halo spin variability.

## Abstract

We investigate the origin, the shape, the scatter, and the cosmic evolution in the observed relationship between specific angular momentum $j_\star$ and the stellar mass $M_\star$ in early-type (ETGs) and late-type galaxies (LTGs). Specifically, we exploit the observed star-formation efficiency and chemical abundance to infer the fraction $f_{\rm inf}$ of baryons that infall toward the central regions of galaxies where star formation can occur. We find $f_{\rm inf}\approx 1$ for LTGs and $\approx 0.4$ for ETGs with an uncertainty of about $0.25$ dex, consistent with a biased collapse. By comparing with the locally observed $j_\star$ vs. $M_\star$ relations for LTGs and ETGs we estimate the fraction $f_j$ of the initial specific angular momentum associated to the infalling gas that is retained in the stellar component: for LTGs we find $f_j\approx 1.11^{+0.75}_{-0.44}$, in line with the classic disc formation picture; for ETGs we infer $f_j\approx 0.64^{+0.20}_{-0.16}$, that can be traced back to a $z<1$ evolution via dry mergers. We also show that the observed scatter in the $j_{\star}$ vs. $M_{\star}$ relation for both galaxy types is mainly contributed by the intrinsic dispersion in the spin parameters of the host dark matter halo. The biased collapse plus mergers scenario implies that the specific angular momentum in the stellar components of ETG progenitors at $z\sim 2$ is already close to the local values, in pleasing agreement with observations. All in all, we argue such a behavior to be imprinted by nature and not nurtured substantially by the environment.

## Full text

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## Figures

21 figures with captions in the complete paper: https://tomesphere.com/paper/1706.02165/full.md

## References

133 references — full list in the complete paper: https://tomesphere.com/paper/1706.02165/full.md

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Source: https://tomesphere.com/paper/1706.02165