A new test of f(R) gravity with the cosmological standard rulers in radio quasars

Abstract

As an important candidate gravity theory alternative to dark energy, a class of f(R) modified gravity, which introduces a perturbation of the Ricci scalar R in the Einstein-Hilbert action, has been extensively applied to cosmology to explain the acceleration of the universe. In this paper, we focus on the recently-released VLBI observations of the compact structure in intermediate-luminosity quasars combined with the angular-diameter-distance measurements from galaxy clusters, which consists of 145 data points performing as individual cosmological standard rulers in the redshift range 0.023 z 2.80, to investigate observational constraints on two viable models in f(R) theories within the Palatini formalism: f1(R)=R-aRb and f2(R)=R-aRR+ab. We also combine the individual standard ruler data with the observations of CMB and BAO, which provides stringent constraints. Furthermore, two model diagnostics, Om(z) and statefinder, are also applied to distinguish the two f(R) models and model. Our results show that (1) The quasars sample performs very well to place constraints on the two f(R) cosmologies, which indicates its potential to act as a powerful complementary probe to other cosmological standard rulers. (2) The model, which corresponds to b=0 in the two f(R) cosmologies is still included within 1σ range. However, there still exists some possibility that may not the best cosmological model preferred by the current high-redshift observations. (3) The information criteria indicate that the cosmological constant model is still the best one, while the f1(R) model gets the smallest observational support. (4) The f2(R) model, which evolves quite different from f1(R) model at early times, still significantly deviates from both f1(R) and model at the present time.