Mass-Temperature relation in $\Lambda$CDM and modified gravity
Abstract
We derive the mass-temperature relation using an improved top-hat model and a continuous formation model which takes into account the effects of the ordered angular momentum acquired through tidal-torque interaction between clusters, random angular momentum, dynamical friction, and modifications of the virial theorem to include an external pressure term usually neglected. We show that the mass-temperature relation differs from the classical self-similar behavior, , and shows a break at keV, and a steepening with a decreasing cluster temperature. We then compare our mass-temperature relation with those obtained in the literature with -body simulations for and symmetron models. We find that the mass-temperature relation is not a good probe to test gravity theories beyond Einstein's general relativity, because the mass-temperature relation of the CDM model is similar to that of the modified gravity theories.
Cite
@article{arxiv.1908.07322,
title = {Mass-Temperature relation in $\Lambda$CDM and modified gravity},
author = {Antonino Del Popolo and Francesco Pace and David F. Mota},
journal= {arXiv preprint arXiv:1908.07322},
year = {2019}
}
Comments
11 pages; 2 figures; matches the published Phys. Rev. D version