Cosmological perturbations and structure formation in nonlocal infrared modifications of general relativity

Abstract

We study the cosmological consequences of a recently proposed nonlocal modification of general relativity, obtained by adding a term m2R\,-2R to the Einstein-Hilbert action. The model has the same number of parameters as , with m replacing , and is very predictive. At the background level, after fixing m so as to reproduce the observed value of M, we get a pure prediction for the equation of state of dark energy as a function of redshift, w DE(z), with w DE(0) in the range [-1.165,-1.135] as M varies over the broad range M∈ [0.20,0.36]. We find that the cosmological perturbations are well-behaved, and the model fully fixes the dark energy perturbations as a function of redshift z and wavenumber k. The nonlocal model provides a good fit to supernova data and predicts deviations from General Relativity in structure formation and in weak lensing at the level of 3-4%, therefore consistent with existing data but readily detectable by future surveys. For the logarithmic growth factor we obtain γ 0.53, to be compared with γ 0.55 in . For the Newtonian potential on subhorizon scales our results are well fitted by (a;k)=[1+μs as] GR(a;k) with a scale-independent μs 0.09 and s 2, while the anisotropic stress is negligibly small.