# NIHAO XIV: Reproducing the observed diversity of dwarf galaxy rotation   curve shapes in LCDM

**Authors:** Isabel M. Santos-Santos, Arianna Di Cintio, Chris B. Brook, Andrea, Macci\`o, Aaron Dutton, Rosa Dom\'inguez-Tenreiro

arXiv: 1706.04202 · 2017-10-17

## TL;DR

This paper demonstrates that incorporating dark matter core formation in simulations reproduces the diverse rotation curves of dwarf galaxies observed in the universe, addressing a key challenge to LCDM cosmology.

## Contribution

It shows that halo expansion leading to core formation explains the observed diversity of dwarf galaxy rotation curves in LCDM simulations, improving upon previous models with universal cuspy profiles.

## Key findings

- NIHAO simulations match observed RC shape diversity
- Core formation depends on stellar-to-halo mass ratio
- Simulations reproduce slowly rising RCs of specific galaxies

## Abstract

The significant diversity of rotation curve (RC) shapes in dwarf galaxies has recently emerged as a challenge to LCDM: in dark matter (DM) only simulations, DM halos have a universal cuspy density profile that results in self-similar RC shapes. We compare RC shapes of simulated galaxies from the NIHAO project with observed galaxies from the homogeneous SPARC dataset. The DM halos of the NIHAO galaxies can expand to form cores, with the degree of expansion depending on their stellar-to-halo mass ratio. By means of the $V_{\rm 2kpc}-V_{\rm Rlast}$ relation (where $V_{\rm Rlast}$ is the outermost measured rotation velocity), we show that both the average trend and the scatter in RC shapes of NIHAO galaxies are in reasonable agreement with SPARC: this represents a significant improvement compared to simulations that do not result in DM core formation, suggesting that halo expansion is a key process in matching the diversity of dwarf galaxy RCs. Note that NIHAO galaxies can reproduce even the extremely slowly rising RCs of IC 2574 and UGC 5750. Revealingly, the range where observed galaxies show the highest diversity corresponds to the range where core formation is most efficient in NIHAO simulations, 50$<V_{\rm Rlast}$\km s$^{-1}<$100. A few observed galaxies in this range cannot be matched by any NIHAO RC nor by simulations that predict a universal halo profile. Interestingly, the majority of these are starbursts or emission-line galaxies, with steep RCs and small effective radii. Such galaxies represent an interesting observational target providing new clues to the process/viability of cusp-core transformation, the relationship between starburst and inner potential well, and the nature of DM.

## Full text

_Full body text omitted from this summary view._ Fetch the complete paper as Markdown: https://tomesphere.com/paper/1706.04202/full.md

## Figures

6 figures with captions in the complete paper: https://tomesphere.com/paper/1706.04202/full.md

## References

111 references — full list in the complete paper: https://tomesphere.com/paper/1706.04202/full.md

---
Source: https://tomesphere.com/paper/1706.04202