Abstract / Description of output
We have simulated the formation of a massive galaxy cluster
(M_{200}^crit = 1.1 × 1015 h-1
M⊙) in a Λ cold dark matter universe using 10
different codes (RAMSES, 2 incarnations of AREPO and 7 of GADGET),
modelling hydrodynamics with full radiative subgrid physics. These codes
include smoothed-particle hydrodynamics (SPH), spanning traditional and
advanced SPH schemes, adaptive mesh and moving mesh codes. Our goal is
to study the consistency between simulated clusters modelled with
different radiative physical implementations - such as cooling, star
formation and thermal active galactic nucleus (AGN) feedback. We compare
images of the cluster at z = 0, global properties such as mass, and
radial profiles of various dynamical and thermodynamical quantities. We
find that, with respect to non-radiative simulations, dark matter is
more centrally concentrated, the extent not simply depending on the
presence/absence of AGN feedback. The scatter in global quantities is
substantially higher than for non-radiative runs. Intriguingly, adding
radiative physics seems to have washed away the marked code-based
differences present in the entropy profile seen for non-radiative
simulations in Sembolini et al.: radiative physics + classic SPH can
produce entropy cores, at least in the case of non cool-core clusters.
Furthermore, the inclusion/absence of AGN feedback is not the dividing
line -as in the case of describing the stellar content - for whether a
code produces an unrealistic temperature inversion and a falling central
entropy profile. However, AGN feedback does strongly affect the overall
stellar distribution, limiting the effect of overcooling and reducing
sensibly the stellar fraction.
Original language | English |
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Pages (from-to) | 2973-2991 |
Journal | Monthly Notices of the Royal Astronomical Society |
Volume | 459 |
Issue number | 3 |
DOIs | |
Publication status | Published - 7 Apr 2016 |
Keywords / Materials (for Non-textual outputs)
- methods: numerical
- galaxies: haloes
- cosmology: theory
- dark matter