Measuring the speed of light with ultra-compact radio quasars

Abstract

In this paper, based on a 2.29 GHz VLBI all-sky survey of 613 milliarcsecond ultra-compact radio sources with 0.0035<z<3.787, we describe a method of identifying the sub-sample which can serve as individual standard rulers in cosmology. If the linear size of the compact structure is assumed to depend on source luminosity and redshift as lm=l Lβ (1+z)n, only intermediate-luminosity quasars (1027 W/Hz<L< 1028 W/Hz) show negligible dependence (|n| 10-3, |β| 10-4), and thus represent a population of such rulers with fixed characteristic length l=11.42 pc. With a sample of 120 such sources covering the redshift range 0.46<z<2.80, we confirm the existence of dark energy in the Universe with high significance under the assumption of a flat universe, and obtain stringent constraints on both the matter density m=0.323+0.245-0.145 and the Hubble constant H0=66.30+7.00-8.50 km sec-1 Mpc-1. Finally, with the angular diameter distances DA measured for quasars extending to high redshifts (z 3.0), we reconstruct the DA(z) function using the technique of Gaussian processes. This allows us to identify the redshift corresponding to the maximum of the DA(z) function: zm=1.70 and the corresponding angular diameter distance DA(zm)=1719.0143.46 Mpc. Similar reconstruction of the expansion rate function H(z) based on the data from cosmic chronometers and BAO gives us H(zm)=176.776.11 km sec-1 Mpc-1. These measurements are used to estimate the speed of light: c=3.039(0.180)× 105 km/s. This is the first measurement of the speed of light in a cosmological setting referring to the distant past.