Exact Recession Velocity and Cosmic Redshift Based on Cosmological Principle and Yang-Mills Gravity

Abstract

Based on the cosmological principle and quantum Yang-Mills gravity in the super-macroscopic limit, we obtain an exact recession velocity and cosmic redshift z, as measured in an inertial frame F F(t,x,y,z). For a matter-dominated universe, we have the effective cosmic metric tensor Gμ(t)=(B2(t),-A2(t),-A2(t),-A2(t)), \ A B t1/2, where t has the operational meaning of time in F frame. We assume a cosmic action S Scos involving Gμ(t) and derive the `Okubo equation' of motion, Gμ(t)∂μ S ∂ S - m2=0, for a distant galaxy with mass m. This cosmic equation predicts an exact recession velocity, r=rH/[1/2 +1/4+r2H2/Co2 ]<Co, where H=A(t)/A(t) and Co=B/A, as observed in the inertial frame F. For small velocities, we have the usual Hubble's law r ≈ rH for recession velocities. Following the formulation of the accelerated Wu-Doppler effect, we investigate cosmic redshifts z as measured in F. It is natural to assume the massless Okubo equation, Gμ(t)∂μ e ∂ e=0, for light emitted from accelerated distant galaxies. Based on the principle of limiting continuation of physical laws, we obtain a transformation for covariant wave 4-vectors between and inertial and an accelerated frame, and predict a relationship for the exact recession velocity and cosmic redshift, z=[(1+Vr)/(1-Vr2)1/2] - 1, where Vr=r/Co<1, as observed in the inertial frame F. These predictions of the cosmic model are consistent with experiments for small velocities and should be further tested.