| E = mc^2 |
Of all the Einstein equations, this one is the only one to survive in Autodynamics. But will it? There are questions as to its validity and no certain tests of its value as of yet. Still, Autodynamics thesis is one of a universe that dynamically changes from energy to mass in a constant flow.
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E=mc^2 does not equal Special Relativity!
There is a popular misconception that the definition of Einstein's "Special Relativity" is the equation E = mc^2. In fact, it is not. This equation is really Einstein's "mass-energy equivalence equation". Einstein published the equation in 1905 paper discussing electron-magnetic radiation (the light spectrum). But this is not "Special Relativity".
Special Relativity comes from the idea that the speed of light is an "absolute" and the equations for mass, time, and length that result from this. Although Einstein's famous equation is not directly related to "Special Relativity", it did greatly influence his thought process when coming up with his "special" theory.
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Mass-Energy Equivalence
Einstein was the first in the world to relate mass and energy with a simple constant: c^2, or the speed of light squared.
This equation can be visualized by taking any mass, and imagine it being turned completely into pure radiation. The resulting total energy would be the mass times "c" times "c". That is a big number. That gave birth to the idea of the atomic bomb. But this does not mean that physicists have decayed any mass entirely, measured the results, and those results agreed with observation. Fact is, even in our most "efficient" atomic bombs, the actual mass converted to energy is extremely small. We have not ever decayed mass completely into pure radiation to test the hypothesis of this equation.
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Mass-Energy Equivalence in Autodynamics
So, does the famous equation "E=mc^2" survive in Autodynamics? The answer is, currently, yes. Carezani discovered the Autodynamic equations using the same steps as Einstein, simply with a correction. He assumes this equation to be true for now. It may be that the equation for energy and mass equivalence is something different where E = m K where "K" is some constant other than c^2. But for now, it is assumed to be correct.
Related information on the faster-than-light layman page.
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| Storm In Physics (2005) |
2nd book published by Dr. Carezani.
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