Monday, March 3, 2014

Using the encoder model to explain fusion



stellarator:
A stellarator is a device used to confine a hot plasma with magnetic fields in order to sustain a controlled nuclear fusion reaction. It is one of the earliest controlled fusion devices, first invented by Lyman Spitzer in 1950 and built the next year at what later became the Princeton Plasma Physics Laboratory. The name refers to the possibility of harnessing the power source of the sun, a stellar object.

Very simply, the new model says a controlled fusion reaction is one in which the planks constant is increased and there is not enough charge to quantize the electron, which then fuses with the nuclear field to propagate Nuclear-elector waves. The encode model says the dimensionality around the fusion is reduced. The intense straight line magnetic force is out of balance with the electron spin. The vacuum dequantizes the electron in an attempt to requantize it to a higher planks level and thus match the magnetic force. There is not enough charge to do so, and the deconstruction of the electron allow the nuclear force to uncurls and wave propagation with the electron field release quantization, the total amount of matter reduced. The vacuum, in this sense, is unable to find the optimum congestion and reduces rank, releasing wave propagation until the lower rank system can requantize to optimum congestion.

So the model assumes plank is only constant within the rank of the vacuum region. Heisenberg constant, the uncertainty constant, always restabilizes to the new rank and now matches, again, the apparent SNR of the system.

Thus, gravitional-magneto wave propagation from a high dimensional system in the universe will always be requantizes lower in our low dimensionality system.  The lower quantization levels cause the directionality to be reduced, and we see the propagation as randomly arriving particles, I would assume. The gravitional component barely noticed, and the magnetic component recoupling with the local environment.

And a low dimensional nuclear-electro propagation would be quantized more finely and appear as a proton with a charge dipole, likely.  Our environment would create matter from such a wave, explaining how a proton could leave a low dimensional environment, which this theory predicts is impossible. An electo-magnetic wave leaving our environment and appearing in a high dimensional environment would look like arriving electrons with magnetic spin.

Smashing protons in the hunt for the Higgs boson would be a double drop of rank. The wave created, momentarily, would be the  weak-strong nuclear, which is quickly quantize into a  strong-nuclear, which is quickly requantized and so on. In our standard model these appear as particle creation and decay.

Characteristic spectrum of differing dimensionality.  Our region is limits by the quantization levels measurable per sample in the vacuum.  Hence there is a lower limit to the frequency transmission of electo-magentic radiation.  There is a higher limit at which quantization levels must increase, raising the rank.

The size of our region is determined when the gravition field is too weak to be measured.

I would think that physicists on earth, assume the standard model is everywhere the same, could be quite confused.  But, likely, I could be completely wrong.

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