The Universe expansion and Energy problems

Abstract

In this paper we construct a physical modelization of the universe expansion. The universe then reduces to a Riemannian space 0.2cm (B(O,R(t)),gt), where R(t) t for t 0, and gt is a time - dependent Riemannian metric which reflects and characterizes the dynamical matter - energy distribution Et(X) on B(O,R(t)) according to the Mach - Einstein principle. Our model allows us to resolve several major problems of Physics. It is consistent in the sense that all Newtonian and classical physical laws are valid as particular cases in classical situations. Moreover, our model permits to recover some confirmed principles and postulates such as the famous Einstein's relationship E = mc2 and to specify some approximate results of modern Physics. After showing, rigorously, the deficiency of the second part of the special relativity second postulate and after specifying the role of the wave quantum Mechanics and the quantum Statistics, we adapt the Einstein's general relativity theory and the (Einstein - de Sitter - Friedmann) homogeneous isotropic cosmology to our setting. This readaptation allows us to determine the age, the size and the total energy of our universe and to prove that only the total energy E, the electromagnetic constant ke2 and the speed of light c are time - independent universal constants. The other fundamental constants of Physics (such as G,h, KB 0.05cm T, α...) are indeed time - dependent and naturally related to the previous ones. Consequently, we realize the unification of all Physics' domains The expanding universe is so reduced to four basic elements (E, c, ke2, t) and dynamically described by a (reviewed) general relativity theory.