# Be it therefore resolved: Cosmological Simulations of Dwarf Galaxies   with Extreme Resolution

**Authors:** Coral Wheeler (1), Philip F. Hopkins (1), Andrew B. Pace (2), Shea, Garrison-Kimmel (1), Michael Boylan-Kolchin (3), Andrew Wetzel (4), James S., Bullock (5), Dusan Keres (6), Claude-Andre Faucher-Giguere (7), Eliot, Quataert (8) ((1) Caltech, (2) TAMU, (3) UT Austin, (4) UC Davis, (5) UC, Irvine, (6) UCSD, (7) Northwestern, (8) UC Berkeley)

arXiv: 1812.02749 · 2019-10-23

## TL;DR

This study uses ultra-high-resolution cosmological simulations to explore the formation, structure, and star formation histories of dwarf galaxies, revealing insights into their internal structures, metallicities, and observability.

## Contribution

It presents the first ultra-high-resolution simulations resolving individual supernova remnants, providing new insights into dwarf galaxy formation and internal structures.

## Key findings

- Ultra-faint dwarfs have early star formation truncated by reionization.
- Classical dwarfs continue star formation to low redshift.
- Simulated dwarf properties match observed sizes and dynamics.

## Abstract

We study a suite of extremely high-resolution cosmological FIRE simulations of dwarf galaxies ($M_{\rm halo} \lesssim 10^{10}$$M_{\odot}$), run to $z=0$ with $30 M_{\odot}$ resolution, sufficient (for the first time) to resolve the internal structure of individual supernovae remnants within the cooling radius. Every halo with $M_{\rm halo} \gtrsim 10^{8.6} M_{\odot}$ is populated by a resolved {\em stellar} galaxy, suggesting very low-mass dwarfs may be ubiquitous in the field. Our ultra-faint dwarfs (UFDs; $M_{\ast}<10^{5}\,M_{\odot}$) have their star formation truncated early ($z\gtrsim2$), likely by reionization, while classical dwarfs ($M_{\ast}>10^{5} M_{\odot}$) continue forming stars to $z<0.5$. The systems have bursty star formation (SF) histories, forming most of their stars in periods of elevated SF strongly clustered in both space and time. This allows our dwarf with $M_{\ast}/M_{\rm halo} > 10^{-4}$ to form a dark matter core $>200$pc, while lower-mass UFDs exhibit cusps down to $\lesssim100$pc, as expected from energetic arguments. Our dwarfs with $M_{\ast}>10^{4}\,M_{\odot}$ have half-mass radii ($R_{\rm 1/2}$) in agreement with Local Group (LG) dwarfs; dynamical mass vs. $R_{1/2}$ and the degree of rotational support also resemble observations. The lowest-mass UFDs are below surface brightness limits of current surveys but are potentially visible in next-generation surveys (e.g. LSST). The stellar metallicities are lower than in LG dwarfs; this may reflect pre-enrichment of the LG by the massive hosts or Pop-III stars. Consistency with lower resolution studies implies that our simulations are numerically robust (for a given physical model).

## Full text

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## Figures

9 figures with captions in the complete paper: https://tomesphere.com/paper/1812.02749/full.md

## References

124 references — full list in the complete paper: https://tomesphere.com/paper/1812.02749/full.md

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Source: https://tomesphere.com/paper/1812.02749