The fraction of dark matter within galaxies from the IllustrisTNG simulations

Mark R. Lovell, Annalisa Pillepich, Shy Genel, Dylan Nelson, Volker Springel, Rüdiger Pakmor, Federico Marinacci, Rainer Weinberger, Paul Torrey, Mark Vogelsberger, Lars Hernquist

Published 2018-01-30Version 1

We use the IllustrisTNG (TNG) cosmological simulations to provide theoretical expectations for the DM mass fractions (DMFs) and circular velocity profiles within the inner regions of haloes where galaxies reside. TNG predicts flat circular velocity curves for $z=0$ MW-like haloes beyond a few kpc from the galaxy centre, in better agreement with observational constraints than its predecessor, Illustris. TNG also predicts an enhancement of the DM mass within the 3D stellar half-mass radius ($r_{\rm half}$) of galaxies ($M_{200c}=10^{10}-10^{13}M_{\odot}$, $z\le 2$) in comparison to their DM-only and Illustris counterparts. This enhancement leads TNG present-day galaxies to be dominated by DM within their inner regions, with $f_{\rm DM} (< r_{\rm half}) \gtrsim 0.5$ at all masses and with a minimum for MW-mass haloes. The DMFs in $z=0$ TNG ellipticals are in broad agreement with the median, but not the scatter of e.g. the observed {\sc sluggs} galaxies, with $f_{\rm DM}(< 2-5 \times r_{\rm half})\sim 0.5-0.9$ in $M_{\rm stars}\gtrsim 10^{10}M_{\odot}$ galaxies. The DMFs measured within $r_{\rm half}$ decline towards higher redshifts, such evolution being dominated by the increase in galaxy size with time. At $z\sim2$, the DMF in disc-like TNG galaxies decreases with increasing galaxy mass, with $f_{\rm DM}(< r_{\rm half}) \sim 0.10-0.65$ for $10^{10} \lesssim M_{\rm stars}/M_{\odot} \lesssim 10^{12}$, and are two times higher than if TNG galaxies resided in NFW DM haloes unaffected by baryonic physics. It remains to be properly assessed whether recent observational estimates of the DMFs at $z\le2$ rule out the contraction of the DM haloes predicted by the TNG model.