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Originally Posted by cyrek1
cyrek reply
However, the HA is radiating a standing continuous sign wave in its energy state depending on its temperature environment from the ground state to a higher state.
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I have to ask this, but if it is radiating, where does its energy come from?
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In outer space, a recombined electron with a proton can radiate a long Lyman wavelenth from the most outer of the atoms regular energy states to the innermost orbit to radiate the longest Lyman wavelength (hypothetical, of course).
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The transition that I think you're describing generates the
shortest wavelength, corresponding to an energy of ~13.6 eV.
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The wave nature of the electron is the result of interactions between its forces. The electron remains a particle during its wave like motions.
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Are you saying that the electron physically moves in a wave-like fashion, and can you quantify what these interactions are and how they lead to the behaviour of the electron?
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You have to understand that what I say may appear to be purely imaginary but I use the knowledge about the nature of these particles to determine their possible dynamic probabilities.
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But in your earlier post, by using the definition of the Ampere in the way that you did, you seem to be implying that the electron is a long linear distribution of charge.
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I call this applied science. Ha HA.
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I'm not sure how it counts as being applied science as I can't see any comparison between any prediction and the real world. I've already shown you how the standard QM approach predicts the 21 cm emission band (among
many other features), and yet your model doesn't seem to be able to make any such claims.