Bibcode
van de Voort, Freeke; Schaye, Joop; Booth, C. M.; Haas, Marcel R.; Dalla Vecchia, C.
Bibliographical reference
Monthly Notices of the Royal Astronomical Society, Volume 414, Issue 3, pp. 2458-2478.
Advertised on:
7
2011
Citations
290
Refereed citations
276
Description
We study the rate at which gas accretes on to galaxies and haloes and
investigate whether the accreted gas was shocked to high temperatures
before reaching a galaxy. For this purpose, we use a suite of large
cosmological, hydrodynamical simulations from the OverWhelmingly Large
Simulations project, which uses a modified version of the smoothed
particle hydrodynamics code GADGET-3. We improve on previous work by
considering a wider range of halo masses and redshifts, by
distinguishing between accretion on to haloes and accretion on to
galaxies, by including important feedback processes and by comparing
simulations with different physics.
Gas accretion is mostly smooth, with mergers only becoming important for
groups and clusters. The specific rate of the gas accretion on to haloes
is, like that for dark matter, only weakly dependent on the halo mass.
For halo masses Mhalo≫ 1011 M⊙,
it is relatively insensitive to feedback processes. In contrast,
accretion rates on to galaxies are determined by radiative cooling and
by outflows driven by supernovae and active galactic nuclei. Galactic
winds increase the halo mass at which the central galaxies grow the
fastest by about two orders of magnitude to Mhalo˜
1012 M⊙.
Gas accretion is bimodal, with maximum past temperatures either of the
order of the virial temperature or ≲105 K. The fraction
of the gas accreted on to haloes in the hot mode is insensitive to
feedback and metal-line cooling. It increases with decreasing redshift,
but is mostly determined by the halo mass, increasing gradually from
less than 10 per cent for ˜1011 M⊙ to
greater than 90 per cent at ˜1013 M⊙. In
contrast, for accretion on to galaxies, the cold mode is always
significant and the relative contributions of the two accretion modes
are more sensitive to feedback and metal-line cooling. On average, the
majority of stars present in any mass halo at any redshift were formed
from the gas accreted in the cold mode, although the hot mode
contributes typically over 10 per cent for Mhalo≳
1011 M⊙.
Thus, while gas accretion on to haloes can be robustly predicted, the
rate of accretion on to galaxies is sensitive to uncertain feedback
processes. Nevertheless, it is clear that galaxies, but not necessarily
their gaseous haloes, are predominantly fed by the gas that did not
experience an accretion shock when it entered the host halo.