Difference between revisions of "The Ether Revisied"
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==Abstract== | ==Abstract== | ||
| − | We will show that the Lorentz transformation applies in Galilean space-time, such that the laws of electromagnetism and classical mechanics become invariant. Assuming the existence of a gas permeating all space and matter, we conclude that the mechanical properties of gases, known for over a century, are sufficient to explain the known physical phenomena such as electromagnetism, light propagation, gravitation, quantum mechanics and the structure of elementary particles, including the photon. | + | We will show that the Lorentz transformation applies in Galilean space-time, such that the laws of electromagnetism and classical mechanics become invariant. Assuming the existence of a gas permeating all space and matter, we conclude that the mechanical properties of gases, known for over a century, are sufficient to explain the known physical phenomena such as electromagnetism, light propagation, gravitation, quantum mechanics and the structure of elementary particles, including the photon. |
| − | [[Category:Gravity]] | + | [[Category:Scientific Paper|ether revisied]] |
| − | [[Category:Aether]] | + | |
| + | [[Category:Gravity|ether revisied]] | ||
| + | [[Category:Aether|ether revisied]] | ||
Latest revision as of 20:01, 1 January 2017
| Scientific Paper | |
|---|---|
| Title | The Ether Revisied |
| Author(s) | Adolphe Martin |
| Keywords | ether, space-time, electromagnetism, gas, matter, light propagation, gravitation, quantum mechanics, elementary particles, photon |
| Published | 1994 |
| Journal | None |
| Pages | 209-216 |
Abstract
We will show that the Lorentz transformation applies in Galilean space-time, such that the laws of electromagnetism and classical mechanics become invariant. Assuming the existence of a gas permeating all space and matter, we conclude that the mechanical properties of gases, known for over a century, are sufficient to explain the known physical phenomena such as electromagnetism, light propagation, gravitation, quantum mechanics and the structure of elementary particles, including the photon.
