Difference between revisions of "CPQM vs. Special Relativity"
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| − | CPQM stands for Classical Physics & Quantum Mechanics. Special Relativity Theory explains many relativistic experiments, but several experiments exist for which the data differ from the values foreseen by this theory. This work shows that CPQM explains the experiments on mass variation, ultimate speed, absorption of electrons, transverse Doppler effect, lifetime extension, etc. It also offers a comparative study between the two theories, and proposes three classical experiments (with some modifications) to distinguish the correct theory.[[Category:Scientific Paper]] | + | CPQM stands for Classical Physics & Quantum Mechanics. Special Relativity Theory explains many relativistic experiments, but several experiments exist for which the data differ from the values foreseen by this theory. This work shows that CPQM explains the experiments on mass variation, ultimate speed, absorption of electrons, transverse Doppler effect, lifetime extension, etc. It also offers a comparative study between the two theories, and proposes three classical experiments (with some modifications) to distinguish the correct theory. |
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| + | [[Category:Scientific Paper|cpqm vs special relativity]] | ||
[[Category:Relativity]] | [[Category:Relativity]] | ||
Revision as of 10:12, 1 January 2017
| Scientific Paper | |
|---|---|
| Title | CPQM vs. Special Relativity |
| Author(s) | Silas Sacheli Santos |
| Keywords | Special Relativity; Keywords: special relativity, mass variation, ultimate speed, transverse Doppler effect, lifetime extension |
| Published | 2003 |
| Journal | Galilean Electrodynamics |
| Volume | 14 |
| Number | 4 |
| Pages | 63-68 |
Abstract
CPQM stands for Classical Physics & Quantum Mechanics. Special Relativity Theory explains many relativistic experiments, but several experiments exist for which the data differ from the values foreseen by this theory. This work shows that CPQM explains the experiments on mass variation, ultimate speed, absorption of electrons, transverse Doppler effect, lifetime extension, etc. It also offers a comparative study between the two theories, and proposes three classical experiments (with some modifications) to distinguish the correct theory.
