The Lyman α forest in f(R) modified gravity

In this work, we analyse the Lyman a forest in cosmological hydrodynamical simulations of Chameleon-type f(R)-gravity with the goal to assess whether the impact of such models is detectable in absorption line statistics. We carry out a set of hydrodynamical simulations with the cosmological simulation code MG-GADGET, including star formation and cooling effects, and create synthetic Lyman alpha absorption spectra from the simulation outputs. We statistically compare simulations with f(R) and ordinary general relativity, focusing on flux probability distribution functions and flux power-spectra, an analysis of the column density and linewidth distributions, as well as the matter power spectrum. We find that the influence of f(R)-gravity on the Lyman alpha forest is rather small. Even models with strong modifications of gravity, like vertical bar(integral) over bar (R0)vertical bar = 10(-4), do not change the statistical Lyman alpha properties by more than 10 per cent. The column density and linewidth distributions are hardly affected at all. It is therefore not possible to get competitive constraints on the background field f(R) using current observational data. An improved understanding of systematics in the observations and a more accurate modelling of the baryonic/radiative physics would be required to allow this in the future. The impact of f(R) on the matter power spectrum in our results is consistent with previous works.