TITLE:
Quantum Neutron Unit Gravity
AUTHORS:
Donald Chakeres, Vola Andrianarijaona
KEYWORDS:
Quantum Gravity, Neutron, Black Holes, Neutron Stars
JOURNAL NAME:
Journal of High Energy Physics, Gravitation and Cosmology,
Vol.3 No.2,
March
29,
2017
ABSTRACT: Quantum gravity and the transformation of a neutron
star or the merger of two neutron stars into a black hole are important topics
in cosmology. According to the Schwarzschild radius relationship, a black hole
arises when two times of the gravitational binding energy of the gravitational system, GBE, equal the annihilation energy of
its total mass. From a quantum perspective, the integer number of neutrons defines
the GBE and mass in the merger of
binary pure neutron stars transforming to a black hole. Therefore, one can
scale all gravitational binding energy relationships by using neutron mass,
energy, distance, time, or frequency equivalents. We define of the
neutron as the binding energy, 1.4188 × 10 J, of a virtual system
of two neutrons separated by the neutron Compton wavelength. Thedivided by a
neutron’s rest mass energy represents a fundamental, dimensionless
proportionality constant, 9.4252 × 10, . The square root of , αG, which we introduce here as a coupling constant, is identical in concept
to the fine structure constant found in electromagnetic physics, but for
gravity. Both αG and inter-relate
the neutron, proton, electron, Bohr radius, speed of light, Planck’s constant, GBE of the electron in hydrogen, and
Planck time. This paper demonstrates a direct conceptual and computational
rationale of why the neutron and its negative beta decay quantum products
accurately can represent a quantum gravitational natural unit system.