Research Article

The Cosmic Black Hole as a Solution of the Relativistic Quantum Mechanical DIRAC Equation

Wim Vegt
Eindhoven University of Technology, the Nethrelands
* Corresponding author
DOI icon 10.24018/ejphysics.2022.4.3.172

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Submitted 2022-04-29
Published 2022-05-21

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Article Main Content

For many physicists, Albert Einstein’s Theory of General Relativity is the top of Physics. A whole new concept, based on a flexible Space-Time Continuum. A wonderful New and Original insight in the Origins of Space and Time. But nowadays physics requires more than a fundamental theory about Space and Time.

The Mathematical foundation for a “Quantum Mechanical Model of the Black Hole” is based on a 10-dimensional Space-Time Continuum.  This article has been written in projections of a 10-Dimensional Space-Time Continuum within an easier to understand 4-Dimensional Space-Time Continuum. For that reason, this theory will not start with “Einstein’s famous Field Equations”,  but the start will be at a very fundamental concept in Physics. Isaac Newton’s 3rd law as a fundament in Classical-  and Quantum Mechanics.

To make the theory of the “Quantum Mechanical Model of the Black Hole” as much understandable as possible, this article starts with a short comprehension of the theory.

Keywords: Black Hole, General Relativity, Quantum Field Theory, Quantum Gravity

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