Abstract
One of the main problems of contemporary physics is to find a quantum description of gravity. This present approach attempts to remedy the problem through the quantization of a finite but large flat Minkowski space-time by means of Fourier expansion of the displacement four vector. By applying second quantization techniques, space-time emerges as a superposition of space-time eigen states or lattices of quantized space-time vibrations also known as gravitons. Each lattice element four vector is a graviton and traces out an elementary four volume (lattice cell). The stress-momentum tensor of each graviton defines its curvature and also the curvature of the associated lattice as described by General Relativity. The eigen states of space-time are found to be separated by a quantum of energy equal to the product of the Hubble constant and the Planck constant. The highest energy state is at Planck energies. This paper also shows that gravitons can be absorbed and emitted by the space-time lattice changing the volume of its primitive cells and that particles of observable matter are associated with a graviton whose frequency is equal to the particle’s Compton frequency which the lattice can absorb producing a perturbation in the lattice. The space-time lattice is found to be unstable and decays by radiating low energy gravitons of energy equal to the product of the Hubble constant and the Planck constant. This decay causes the space-time superstructure to expand. The graviton is seen a composite spin 2 particle made from a combination of spin half components of the displacement four vector elements. The spin symmetry of its constituent elements can breakdown to give rise to other vector or scalar bosons. Dark Matter is seen as a consequence of Bose-Einstein statistics of gravitons which results in some regions of the lattice having more energy than others.
Highlights
Observed phenomena can be explained either by invoking the explanatory power of Quantum Mechanics or General Relativity
By applying second quantization techniques, space-time emerges as a superposition of space-time eigen states or lattices of quantized space-time vibrations known as gravitons
The eigen states of space-time are found to be separated by a quantum of energy equal to the product of the Hubble constant and the Planck constant
Summary
Observed phenomena can be explained either by invoking the explanatory power of Quantum Mechanics or General Relativity. First it eliminates the need of points in space-time that are the source of many divergences in the current theory of elementary particles in which particles are considered as point like dimensionless particles These divergences first manifested as early as in classical electromagnetic field theory, in which there occurs a Coulomb divergence. The approach that is presented in this paper agrees with LQG in as far as that the very fabric of space-time is responsible for manifesting gravity and that time evolution progresses in quantized steps as well as in the existence of quantized volume elements. This current paper further explains dark matter and the root causes of the expansion of spacetime. This aspect is intrinsic in this present approach to Quantum Gravity
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