How universe evolves with cosmological and gravitational constants

Abstract

With a basic varying space-time cutoff , we study a regularized and quantized Einstein-Cartan gravitational field theory and its domains of ultraviolet-unstable fixed point g ir 0 and ultraviolet-stable fixed point g uv≈ 4/3 of the gravitational gauge coupling g=(4/3)G/G Newton. Because the fundamental operators of quantum gravitational field theory are dimension-2 area operators, the cosmological constant is inversely proportional to the squared correlation length -2. The correlation length characterizes an infrared size of a causally correlate patch of the universe. The cosmological constant and the gravitational constant G are related by a generalized Bianchi identity. As the basic space-time cutoff decreases and approaches to the Planck length pl, the universe undergoes inflation in the domain of the ultraviolet-unstable fixed point g ir, then evolves to the low-redshift universe in the domain of ultraviolet-stable fixed point g uv. We give the quantitative description of the low-redshift universe in the scaling-invariant domain of the ultraviolet-stable fixed point g uv, and its deviation from the can be examined by low-redshift (z 1) cosmological observations, such as supernova Type Ia.