Light, Gregory L. (2019) Quantum Mechanics by General Relativity. Applied Physics Research, 11 (2). p. 1. ISSN 1916-9639
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Abstract
In the framework of General Relativity we explain the creation of all particles, ordinary and anti, in two chiral directions, with multiple generations, as well as electromagnetism and the strong nuclear force. Quantum mechanics is well-known to have its foundational problems revolving around the wave-particle duality, which actually has an exact solution, viz., a diagonal spacetime manifold that admits any particle of energy coupled with its wave of energy co-existing at the same spacetime (t + it, x + iy, y + iz, z + ix). I.e., a photon can travel along x = ct with its associated electromagnetic wave spinning from y to z in circular motion as (y = cos t, z = sin t) ≡ eit. The construct of diagonal manifold, seemingly artificial, is fundamental in differential topology as it leads to the Euler characteristic. That Nature is inherently of duality cannot have a more evident example than that of the complex number x + iy, where 1 implies a linear motion in R and i = eπ2 i implies a circular motion along S 1. That the quantum wave itself possesses energy can be argued simply as: wave = probability = frequency = energy by Planck’s formula. By assigning energy entirely to particle, quantum mechanics has missed an entire copy of the Universe (the wave universe treated as the quantum vacuum).
Item Type: | Article |
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Subjects: | Oalibrary Press > Physics and Astronomy |
Depositing User: | Managing Editor |
Date Deposited: | 17 Apr 2023 04:47 |
Last Modified: | 05 Mar 2024 03:56 |
URI: | http://asian.go4publish.com/id/eprint/1860 |