N-body simulations, halo mass functions, and halo density profile in f(T) gravity

Abstract

We perform N-body simulations for f(T) gravity using the ME-Gadget code, in order to investigate for the first time the structure formation process in detail. Focusing on the power-law model, and considering the model-parameter to be consistent within 1σ with all other cosmological datasets (such as SNIa, BAO, CMB, CC), we show that there are clear observational differences between cosmology and f(T) gravity, due to the modifications brought about the latter in the Hubble function evolution and the effective Newton s constant. We extract the matter density distribution, matter power spectrum, counts-in-cells, halo mass function and excess surface density (ESD) around low density positions (LDPs) at present time. Concerning the matter power spectrum we find a difference from scenario, which is attributed to about 2/3 to the different expansion and to about 1/3 to the effective gravitational constant. Additionally, we find a difference in the cells, which is significantly larger than the Poisson error, which may be distinguishable with weak-lensing reconstructed mass maps. Moreover, we show that there are different massive halos with mass M>1014M/h, which may be distinguishable with statistical measurements of cluster number counting, and we find that the ESD around LDPs is mildly different. In conclusion, high-lighting possible smoking guns, we show that large scale structure can indeed lead us to distinguish General Relativity and cosmology from f(T) gravity.