Vector Theory of Gravity: quantum and classical effects, renormalization

TL;DR

This paper introduces a vector theory of gravity that is quantized, renormalizable, and capable of explaining quantum effects, black holes, dark energy, and binary pulsar behavior, offering a unified approach to gravity.

Contribution

It presents the first quantization of gravity within a vector framework and demonstrates its renormalizability, addressing quantum effects and cosmological phenomena.

Findings

Vector gravity theory is renormalizable.

Black holes of Schwarzschild type can exist in this theory.

The theory explains dark energy and universe acceleration.

Abstract

In this work, we make quantization of gravitation interaction within the framework of a vector theory of gravitation for the first time. The work demonstrates that this theory meets the requirement of renormalizability. Here we consider some quantum effects, particularly graviton scattering on fermion and corrections to the Newton's. Gravitational energy sign changing mechanism and classical transition on small scale is discussed. It is shown that within this theory black holes of Schwarzschield hole type can exist. Problem of dark energy structure and acceleration of Universe expansion is investigated. We also consider the behavior of binary pulsars in the vector theory of gravitation.