Physical Review & Research International, ISSN: 2231-1815,Vol.: 3, Issue.: 4 (October-December)
Quantum Gravity and the Holographic Mass
Nassim Haramein1* 1Director of Research, Hawaii Institute for Unified Physics, P.O. Box 1440, Kilauea, HI 96754.
1Director of Research, Hawaii Institute for Unified Physics, P.O. Box 1440, Kilauea, HI 96754.
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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 0.069x10-24gm of the CODATA value and when the 2010 muonic proton charge radius measurement is utilized we find a deviation of 0.001x10-24gm 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.
Quantum gravity; holographic principle; Schwarzschild solution; proton charge radius; strong interaction; Yukawa potential.
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