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

Iryna Butsky, Andrea V. Macciò, Aaron A. Dutton, Liang Wang, Greg S. Stinson, Camilla Penzo, Xi Kang, Ben W. Keller, James Wadsley

Published 2015-03-16Version 1

We show the effect of galaxy formation on the dark matter (DM) distribution across a wide range of halo masses. We focus on how baryon physics changes the dark matter halo shape, the so called "pseudo phase-space density distribution" and the velocity distribution within the virial radius, Rvir and in the solar neighborhood. This study is based on the NIHAO galaxy formation simulations, a large suite of cosmological zoom-in simulations. The galaxies reproduce key properties of observed galaxies, and hence offer unique insight into how baryons change the dark matter morphology and kinematics. When compared to dark matter only simulations, the NIHAO haloes have similar shapes at Rvir, but are substantially rounder inside ~0.1 Rvir. In DM-only simulations the inner halo has a minor-to-major axis ratio of c/a~0.5. In hydro simulations c/a increases with halo mass and integrated star formation efficiency, reaching ~0.8 at the Milky Way mass, reconciling a long-standing conflict between observations and DM only simulations. The radial profile of the phase-space Q parameter is best fit with a single power law in DM-only simulations, but shows a substantial flattening within ~0.1 Rvir, with hydro. Finally, the global velocity distribution of DM is similar in both DM-only and hydro simulations, but in the solar neighborhood, hydro galaxies deviate substantially from Maxwellian. Instead, dark matter particles show a more symmetric distribution, roughly Gaussian, around the mean, which has implications for direct DM detection experiments. Our results show that the comparison of theoretical predictions with observational data can no longer rely on pure collisionless simulations, but must include the effects of visible matter.