We find an exact quantized expression of the Schwarzschild solution to Einstein’s field equations utilizing spherical Planck units in a generalized holographic approach. We consider vacuum fluctuations within volumes as well as on horizon surfaces, generating a discrete spacetime quantization and a novel quantized approach to gravitation. When applied at the quantum scale, utilizing the charge radius of the proton, we find values for the rest mass of the proton within 0.069×10-24gm of the CODATA value and when the 2010 muonic proton charge radius measurement is utilized we find a deviation of 0.001×10-24gm from the proton rest mass. We identify a fundamental mass ratio between the vacuum oscillations on the surface horizon and the oscillations within the volume of a proton and find a solution for the gravitational coupling constant to the strong interaction. We derive the energy, angular frequency, and period for such a system and determine its gravitational potential considering mass dilation. We find the force range to be closely correlated with the Yukawa potential typically utilized to illustrate the exponential drop-off of the confining force. Zero free parameters or hidden variables are utilized.
AdamApollo AmiraValBaker astronomy Astrophysics Black holes Casimir effect chemistry comet Community Conciousness Consciousness cosmic rays cosmology dark matter electron fractal Holographic Principle InesUrdaneta JohannaDeinert laser Life science light magnetic field NassimHaramein neurobiology neutrinos OlivierAlirol Particle physics planets proton quantum entanglement quantum gravity Quantum Mechanics quantum physics quasar retrocausality Science Simulation solstice Standard Model superconductivity vacuum water science William Brown WilliamBrown