Utility of observational Hubble parameter data on dark energy evolution

Abstract

Aiming at exploring the nature of dark energy, we use thirty-six observational Hubble parameter data (OHD) in the redshift range 0 ≤slant z ≤slant 2.36 to make a cosmological model-independent test of the two-point Omh2(z2;z1) diagnostic. In , we have Omh2 mh2, where m is the matter density parameter at present. We bin all the OHD into four data points to mitigate the observational contaminations. By comparing with the value of mh2 which is constrained tightly by the Planck observations, our results show that in all six testing pairs of Omh2 there are two testing pairs are consistent with at 1σ confidence level (CL), whereas for another two of them can only be accommodated at 2σ CL. Particularly, for remaining two pairs, is not compatible even at 2σ CL. Therefore it is reasonable that although deviations from exist for some pairs, cautiously, we cannot rule out the validity of . We further apply two methods to derive the value of Hubble constant H0 utilizing the two-point Omh2(z2;z1) diagnostic. We obtain H0 = 71.231.54 km \ s-1 \ Mpc-1 from inverse variance weighted Omh2 value (method (I)) and H0 = 69.371.59 km \ s-1 \ Mpc-1 that the Omh2 value originates from Planck measurement (method (II)), both at 1σ CL. Finally, we explore how the error in OHD propagate into w(z) at certain redshift during the reconstruction of w(z). We argue that the current precision on OHD is not sufficient small to ensure the reconstruction of w(z) in an acceptable error range, especially at the low redshift