Observational constraints from SNe Ia and Gamma-Ray Bursts on a clumpy universe

Abstract

The luminosity distance describing the effect of local inhomogeneities in the propagation of light proposed by Zeldovich-Kantowski-Dyer-Roeder (ZKDR) is tested with two probes for two distinct ranges of redshifts: supernovae Ia (SNe Ia) in 0.015 < z < 1.414 and gamma-ray bursts (GRBs) in 1.547 < z < 3.57. Our analysis is performed by a Markov Chain Monte Carlo (MCMC) code that allows us to constrain the matter density parameter m as well as the smoothness parameter α that measures the inhomogeneous-homogeneous rate of the cosmic fluid in a flat model. The obtained best fits are (m=0.285+0.019-0.018, α= 0.856+0.106-0.176) from SNe Ia and (m=0.259+0.028-0.028, α=0.587+0.201-0.202) from GRBs, while from the joint analysis the best fits are (m=0.284+0.021-0.020, α= 0.685+0.164-0.171) with a 2 red=0.975. The value of the smoothness parameter α indicates a clumped universe however it does not have an impact on the amount of dark energy (cosmological constant) needed to fit observations. This result may be an indication that the Dyer-Roeder approximation does not describe in a precise form the effects of clumpiness in the expansion of the universe.