Bibcode
Font, A. S.; McCarthy, I. G.; Crain, R. A.; Theuns, T.; Schaye, J.; Wiersma, R. P. C.; Dalla Vecchia, C.
Bibliographical reference
Monthly Notices of the Royal Astronomical Society, Volume 416, Issue 4, pp. 2802-2820.
Advertised on:
10
2011
Citations
264
Refereed citations
234
Description
We use the Galaxies-Intergalactic Medium Interaction Calculation (GIMIC)
suite of cosmological hydrodynamical simulations to study the formation
of stellar spheroids of Milky Way mass disc galaxies. The simulations
contain accurate treatments of metal-dependent radiative cooling, star
formation, supernova feedback and chemodynamics, and the large volumes
that have been simulated yield an unprecedentedly large sample of
≈400 simulated ˜L* disc galaxies. The simulated
galaxies are surrounded by low-mass, low surface brightness stellar
haloes that extend out to ˜100 kpc and beyond. The diffuse stellar
distributions bear a remarkable resemblance to those observed around the
Milky Way, M31 and other nearby galaxies, in terms of mass density,
surface brightness and metallicity profiles. We show that in situ star
formation typically dominates the stellar spheroids by mass at radii of
r≲ 30 kpc, whereas accretion of stars dominates at larger radii and
this change in origin induces a change in the slope of the surface
brightness and metallicity profiles, which is also present in the
observational data. The system-to-system scatter in the in situ mass
fractions of the spheroid, however, is large and spans over a factor of
4. Consequently, there is a large degree of scatter in the shape and
normalization of the spheroid density profile within r≲ 30 kpc
(e.g. when fitted by a spherical power-law profile, the indices range
from -2.6 to -3.4). We show that the in situ mass fraction of the
spheroid is linked to the formation epoch of the system. Dynamically,
older systems have, on average, larger contributions from in situ star
formation, although there is significant system-to-system scatter in
this relationship. Thus, in situ star formation likely represents the
solution to the long-standing failure of pure accretion-based models to
reproduce the observed properties of the inner spheroid.