Galaxy clustering determined from numerical cosmological simulations

Adrian Jenkins (Durham); A.H. Nelson (Cardiff)(The Virgo consortium); C.S. Frenk (Durham); F.R. Pearce (Durham); G. Efstathiou (Cambridge); H.M.P. Couchman (UWO); J.A. Peacock (Edinburgh); J.M. Colberg (MPA); P.A. Thomas (Sussex); S.D.M. White (MPA)

arxiv: astro-ph/9906039 · v1 · submitted 1999-06-02 · 🌌 astro-ph

Galaxy clustering determined from numerical cosmological simulations

Adrian Jenkins (Durham) , C.S. Frenk (Durham) , F.R. Pearce (Durham) , P.A. Thomas (Sussex) , J.M. Colberg (MPA) , S.D.M. White (MPA) , H.M.P. Couchman (UWO) , J.A. Peacock (Edinburgh)

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G. Efstathiou (Cambridge) A.H. Nelson (Cardiff)(The Virgo consortium)

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keywords galaxiesgalaxylcdmclusteringcorrelationdispersionsfunctionmodel

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We have simulated the growth of structure in two 100 Mpc boxes for LCDM and SCDM universes. These N-body/SPH simulations include a gaseous component which is able to cool radiatively. A fraction of the gas cools into cold dense objects which we identify as galaxies. In this article we give a preliminary analysis of the clustering behaviour of these galaxies concentrating on the LCDM model. We find a galaxy correlation function which is very close to a power law and which evolves relatively little with redshift. The pairwise dispersions of the galaxies are significantly lower than the dark matter. The LCDM model gives a surprisingly good match to the observational determinations of the galaxy correlation function and pairwise dispersions.

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Galaxy clustering determined from numerical cosmological simulations

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