Dynamical difference between the cD galaxy and the diffuse, stellar component in simulated galaxy clusters

Dynamical difference between the cD galaxy and the diffuse, stellar component in simulated galaxy clusters

Member galaxies within galaxy clusters nowadays can be routinely identified in cosmological, hydrodynamical simulations using methods based on identifying self bound, locally over dense substructures. However, distinguishing the central galaxy from the stellar diffuse component within clusters is no...

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Bibliographic Details
Published in:Monthly notices of the Royal Astronomical Society Vol. 405; no. 3; pp. 1544 - 1559
Main Authors: Dolag, K., Murante, G., Borgani, S.
Format: Journal Article
Language:English
Published: Oxford, UK Blackwell Publishing Ltd 01-07-2010
Wiley-Blackwell
Oxford University Press
Subjects:
Astronomy
cosmology: theory
Diffusion
Earth, ocean, space
Exact sciences and technology
galaxies: cluster: general
galaxies: evolution
hydrodynamics
methods: numerical
Stars & galaxies
hydrodynamics
methods: numerical
galaxies: cluster: general
galaxies: evolution
cosmology: theory
Galaxy evolution
Elliptical galaxies
Digital simulation
Numerical method
Velocity distribution
Substructure
Galaxy clusters
Algorithms
Spatial distribution
Star formation
Dynamics
Stellar population
Hydrodynamic model
Cosmology
Virial mass
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Summary:Member galaxies within galaxy clusters nowadays can be routinely identified in cosmological, hydrodynamical simulations using methods based on identifying self bound, locally over dense substructures. However, distinguishing the central galaxy from the stellar diffuse component within clusters is notoriously difficult, and in the centre it is not even clear if two distinct stellar populations exist. Here, after subtracting all member galaxies, we use the velocity distribution of the remaining stars and detect two dynamically, well-distinct stellar components within simulated galaxy clusters. These differences in the dynamics can be used to apply an unbinding procedure which leads to a spatial separation of the two components into a cD and a diffuse stellar component (DSC). Applying our new algorithm to a cosmological, hydrodynamical simulation we find that – in line with previous studies – these two components have clearly distinguished spatial and velocity distributions as well as different star formation histories. We show that the DSC fraction – which can broadly be associated with the observed intracluster light – does not depend on the virial mass of the galaxy cluster and is much more sensitive to the formation history of the cluster. We conclude that the separation of the cD and the DSC in simulations, based on our dynamical criteria, is more physically motivated than current methods which depend on implicit assumptions on a length-scale associated with the cD galaxy and therefore represent a step forward in understanding the different stellar components within galaxy clusters. Our results also show the importance of analysing the dynamics of the DSC to characterize its properties and understand its origin.
Bibliography:istex:C24E83CCF8270025691EDB83FD0BE7797E53271E
ark:/67375/HXZ-QLM02KTW-8
ObjectType-Article-1
SourceType-Scholarly Journals-1
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ISSN:0035-8711
1365-2966
DOI:10.1111/j.1365-2966.2010.16583.x