Abstract
Although the gravitational constant (G) does not explicitly occur in the Maxwell Wave Equations, this paper will show that G is indeed implicitly contained in them. The logical consequence hereby is that electromagnetic radiation is associated with dynamic gravitation and not—as assumed in Einstein’s Special Theory of Relativity—with “static” gravitation, dynamic gravitation being at the time unknown. According to the Maxwell Wave Equations, gravitation experiences the same dynamic (speed of light c) as electromagnetic radiation and must therefore also be of a quantum nature. There must exist an equal number of gravitational quanta as there are photons. Since photons do not possess a baryonic rest mass but only a relativistic mass, this mass must be nonbaryonic in nature—precisely as their dynamic gravitation.
Highlights
For more detailed information on the nature of dynamic gravitation of photons, please refer to the paper by Guido Zbiral: The “Dynamic Gravitation of Photons: A Hitherto Unknown Physical Quantity”
The vectors for the electrical component E and the magnetic component B of the electromagnetic wave are perpendicular to the direction of propagation and are transversal waves; the Efield and the B-field are themselves mutually perpendicular; both fields are completely symmetrical and —in regard to their energy—completely equivalent
Both of these converted wave equations contain the Gravitational Constant G and can be interpreted as follows: Since the two dynamic vector fields E and B transport electrical and magnetic energy along their respective axes with them, each of these fields are associated with G, i.e., both components of the electromagnetic wave are subject to gravitation
Summary
For more detailed information on the nature of dynamic gravitation of photons, please refer to the paper by Guido Zbiral: The “Dynamic Gravitation of Photons: A Hitherto Unknown Physical Quantity”. 2. The Dynamic Gravitation of Photons from the Perspective of Maxwell’s Wave Equations The Maxwell’s Wave Equations for the x-axis are: [1] [2]
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