Cosmic Time Transformations in Cosmological Relativity

Abstract

The relativity of cosmic time is developed within the framework of Cosmological Relativity in five dimensions of space, time and velocity. A general linearized metric element is defined to have the form ds2 = (1+φ) c2 dt2 - dr2 + (1+) τ2 dv2, where the coordinates are time t, radial distance r=x2 + y2 + z2 for spatials x, y and z, and velocity v, with c the speed of light in vacuum and τ the Hubble-Carmeli time constant. The metric is accurate to first order in t/τ and v/c. The fields φ and are general functions of the coordinates. By showing that φ = , a metric of the form ds2 = c2 dt2 - dr2 + τ2 dv2 is obtained from the general metric, implying that the universe is flat. For cosmological redshift z, the luminosity distance relation DL (z,t) = r (1 + z) / 1 - t2 / τ2 is used to fit combined distance moduli from Type Ia Supernovae up to z < 1.5 and Gamma-Ray Bursts up to z < 7, from which a value of M = 0.800 0.080 is obtained for the matter density parameter at the present epoch. Assuming a baryon density of B = 0.038 0.004, a rest mass energy of ( 9.79 0.47 ) \, GeV is predicted for the anti-baryonic Y and the * particles which decay from a hypothetical X1 particle. The cosmic aging function g1(z,t)= ( 1 + z) ( 1 - t2 / τ2 ) makes good fits to light curve data from two reports of Type 1a supernovae and in fitting to simulated quasar like light curve power spectra separated by redshift z ≈ 1. We determine the multipole of the first acoustic peak of the Cosmic Microwave Background radiation anisotropy to be l ≈ 224 5 and a sound horizon of θsh0 ≈ (0.805 0.020 ) on today's sky.