Quantising general relativity using QED theory, an overview and extension

We summarise and discuss some of our previous results, which show that Bohr's theory of the one-electron atom may be derived from the theory underpinning Quantum ElectroDynamics (QED) or vice versa, and that General Relativity may also be derived from QED theory in the classical limit, if we us...

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Veröffentlicht in:	arXiv.org 2004-01
1. Verfasser:	Bell, Sarah B M
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Sprache:	eng
Schlagworte:	Angular momentum Hierarchies Quantum electrodynamics Quantum theory Relativity Self-similarity Theory of relativity
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description	We summarise and discuss some of our previous results, which show that Bohr's theory of the one-electron atom may be derived from the theory underpinning Quantum ElectroDynamics (QED) or vice versa, and that General Relativity may also be derived from QED theory in the classical limit, if we use Newtonian mechanics in the right frame and self-similar tesseral hierarchies. We circumvent Newton's arguments against Descartes' vortex theory to show that the inverse square law for a force combined with the equation of circular motion and Bohr's quantisation of angular momentum may be derived from the vortex theory and Special Relativity. We remark on the electro-weak interaction, the number of dimensions needed, and their connection with tesseral hierarchies.
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We circumvent Newton's arguments against Descartes' vortex theory to show that the inverse square law for a force combined with the equation of circular motion and Bohr's quantisation of angular momentum may be derived from the vortex theory and Special Relativity. 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subjects	Angular momentum Hierarchies Quantum electrodynamics Quantum theory Relativity Self-similarity Theory of relativity
title	Quantising general relativity using QED theory, an overview and extension
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