The mass distribution in the outskirts of clusters of galaxies as a probe of the theory of gravity

Abstract

We show that , the radial location of the minimum in the differential radial mass profile M(r) of a galaxy cluster, can probe the theory of gravity. We derived M(r) of the dark matter halos of galaxy clusters from N-body cosmological simulations that implement two different theories of gravity: standard gravity in the model, and f(R). We extracted 49169 dark matter halos in 11 redshift bins in the range 0≤ z≤ 1 and in three different mass bins in the range 0.9<M200c/1014h-1M<11. We investigated the correlation of with the redshift and the mass accretion rate (MAR) of the halos. We show that decreases from 3R200c to 2R200c when z increases from 0 to 1 in the model. At z 0.1, decreases from 2.8R200c to 2.5R200c when the MAR increases from 104h-1M~yr-1 to 2× 105h-1M~yr-1. In the f(R) model, is 15% larger than in . The median test shows that for samples of 400 dark matter halos at z≤ 0.8, is able to distinguish between the two theories of gravity with a p-value 10-5. Upcoming advanced spectroscopic and photometric programs will allow a robust estimation of the mass profile of enormous samples of clusters up to large clustercentric distances. These samples will allow us to statistically exploit as probe of the theory of gravity, which complements other large-scale probes.

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