dorsal/arxiv
View SchemaThe Physical Reality Underlying the Relativistic Mechanics and the Gravitational Interaction
| Authors | Maurizio Michelini |
|---|---|
| Categories | |
| ArXiv ID | physics/0607136 |
| URL | https://arxiv.org/abs/physics/0607136 |
Abstract
In the present paradigm the space is filled with very high flux of very small quanta whose wavelength equals the Planck's length. The quantum energy is very small, so the relevant Planck constant ho is much smaller than the usual h. This physical paradigm imposes to the motion the conservation of energy and momentum, as well as the laws of the relativistic mechanics. The strong version of the equivalence principle, which requires both inertia and gravitation come from a unique phenomenon, is the relevant test to verify the physical reality of the cosmic quanta. Through Compton's interaction each quantum colliding two masses gives them a little momentum which produces a newtonian force pushing the masses each towards other. The constant G depends on the quanta characteristics, so the Newton's gravitational mass does no longer holds. The new gravitational force of stars depends on the reducing quantum energy, so G multiplies by a gravity factor (greater than 1) depending on the star density. The highest number (200-300) pertains to the neutron stars, which increment notably their accretion capacity. This property may explain the mistery of the obscure supermassive bodies whose gravitational effects rise up to 3.7 million times the Sun effects. Current theories do not give a convincing explanation of this phenomenon.
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"abstract": "In the present paradigm the space is filled with very high flux of very small\nquanta whose wavelength equals the Planck\u0027s length. The quantum energy is very\nsmall, so the relevant Planck constant ho is much smaller than the usual h.\nThis physical paradigm imposes to the motion the conservation of energy and\nmomentum, as well as the laws of the relativistic mechanics. The strong version\nof the equivalence principle, which requires both inertia and gravitation come\nfrom a unique phenomenon, is the relevant test to verify the physical reality\nof the cosmic quanta. Through Compton\u0027s interaction each quantum colliding two\nmasses gives them a little momentum which produces a newtonian force pushing\nthe masses each towards other. The constant G depends on the quanta\ncharacteristics, so the Newton\u0027s gravitational mass does no longer holds. The\nnew gravitational force of stars depends on the reducing quantum energy, so G\nmultiplies by a gravity factor (greater than 1) depending on the star density.\nThe highest number (200-300) pertains to the neutron stars, which increment\nnotably their accretion capacity. This property may explain the mistery of the\nobscure supermassive bodies whose gravitational effects rise up to 3.7 million\ntimes the Sun effects. Current theories do not give a convincing explanation of\nthis phenomenon.",
"arxiv_id": "physics/0607136",
"authors": [
"Maurizio Michelini"
],
"categories": [
"physics.gen-ph"
],
"title": "The Physical Reality Underlying the Relativistic Mechanics and the Gravitational Interaction",
"url": "https://arxiv.org/abs/physics/0607136"
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