# NIHAO XVIII: Origin of the MOND phenomenology of galactic rotation   curves in a LCDM universe

**Authors:** Aaron A. Dutton (NYUAD), Andrea V. Macci\`o (NYUAD, MPIA), Aura Obreja, (USM, NYUAD), Tobias Buck (MPIA)

arXiv: 1902.06751 · 2019-03-06

## TL;DR

This study demonstrates that the radial-acceleration-relation (RAR), a core aspect of MOND phenomenology, naturally emerges from LCDM galaxy formation simulations, with implications for understanding galaxy rotation curves and the limitations of MOND.

## Contribution

The paper shows that the RAR arises naturally in LCDM simulations and explores the dependence of scatter on stellar mass, challenging the assumptions of MOND.

## Key findings

- RAR is reproduced in LCDM simulations with low scatter.
- Scatter increases at lower stellar masses, inconsistent with MOND assumptions.
- MOND fits most galaxy rotation curves but fails in dwarf galaxies.

## Abstract

The phenomenological basis for Modified Newtonian Dynamics (MOND) is the radial-acceleration-relation (RAR) between the observed acceleration, $a=V^2_{rot}(r)/r$, and the acceleration accounted for by the observed baryons (stars and cold gas), $a_{bar}=V_{bar}^2(r)/r$. We show that the RAR arises naturally in the NIHAO sample of 89 high-resolution LCDM cosmological galaxy formation simulations. The overall scatter from NIHAO is just 0.079 dex, consistent with observational constraints. However, we show that the scatter depends on stellar mass. At high masses ($10^9 <M_{star} <10^{11}$ Msun) the simulated scatter is just $\simeq 0.04$ dex, increasing to $\simeq 0.11$ dex at low masses ($10^7 < M_{star} <10^{9}$Msun). Observations show a similar dependence for the intrinsic scatter. At high masses the intrinsic scatter is consistent with the zero scatter assumed by MOND, but at low masses the intrinsic scatter is non-zero, strongly disfavoring MOND. Applying MOND to our simulations yields remarkably good fits to most of the circular velocity profiles. In cases of mild disagreement the stellar mass-to-light ratio and/or "distance" can be tuned to yield acceptable fits, as is often done in observational mass models. In dwarf galaxies with $M_{star}\sim10^6$Msun MOND breaks down, predicting lower accelerations than observed and in our LCDM simulations. The assumptions that MOND is based on (e.g., asymptotically flat rotation curves, zero intrinsic scatter in the RAR), are approximately, but not exactly, true in LCDM. Thus if one wishes to go beyond Newtonian dynamics there is more freedom in the RAR than assumed by MOND.

## Full text

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## Figures

47 figures with captions in the complete paper: https://tomesphere.com/paper/1902.06751/full.md

## References

42 references — full list in the complete paper: https://tomesphere.com/paper/1902.06751/full.md

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Source: https://tomesphere.com/paper/1902.06751