NIHAO project II: Halo shape, phase-space density and velocity distribution of dark matter in galaxy formation simulations

TL;DR

This study uses the NIHAO cosmological simulations to analyze how galaxy formation influences dark matter halo shapes, phase-space density, and velocity distributions, revealing significant modifications especially within inner halo regions.

Contribution

The paper demonstrates that galaxy formation processes lead to rounder inner halo shapes and alter phase-space and velocity distributions, providing insights into dark matter properties in galaxy formation.

Findings

Halo shapes are rounder inside 0.1 R_vir in NIHAO compared to DM-only.

Halo shape correlates with halo mass and star formation efficiency.

Velocity distribution in the solar neighborhood deviates from Maxwellian, being more Gaussian.

Abstract

We use the NIHAO (Numerical Investigation of Hundred Astrophysical Objects) cosmological simulations to study the effects of galaxy formation on key properties of dark matter (DM) haloes. NIHAO consists of $\simeq 90$ high-resolution SPH simulations that include (metal-line) cooling, star formation, and feedback from massive stars and SuperNovae, and cover a wide stellar and halo mass range: $10^6 < M_* / M_{\odot} < 10^{11}$ ( $10^{9.5} < M_{\rm halo} / M_{\odot} < 10^{12.5}$). When compared to DM-only simulations, the NIHAO haloes have similar shapes at the virial radius, R_{\rm vir}, but are substantially rounder inside $\simeq 0.1R_{\rm vir}$. In NIHAO simulations $c/a$ increases with halo mass and integrated star formation efficiency, reaching $\sim 0.8$ at the Milky Way mass (compared to 0.5 in DM-only), providing a plausible solution to the long-standing conflict between observations and DM-only simulations. The radial profile of the phase-space $Q$ parameter ($\rho/\sigma^3$) is best fit with a single power law in DM-only simulations, but shows a flattening within $\simeq 0.1R_{\rm vir}$ for NIHAO for total masses $M>10^{11} M_{\odot}$. Finally, the global velocity distribution of DM is similar in both DM-only and NIHAO simulations, but in the solar neighborhood, NIHAO galaxies deviate substantially from Maxwellian. The distribution is more symmetric, roughly Gaussian, with a peak that shifts to higher velocities for Milky Way mass haloes. We provide the distribution parameters which can be used for predictions for direct DM detection experiments. Our results underline the ability of the galaxy formation processes to modify the properties of dark matter haloes.