Like this Mansuripur fellow who found the Ice Cream swirl before I could. Now he is going to get the Swedish Banana. Anyway, he found the extra momentum term in the Lorentz charge force law. I am sure the term he found is related to small and big bubbles doing the swirl in wave motion.
So, the modes of co-movement between large and small bubbles will define my 'ruler' down to space curvature. In other words, the big and small bubbles are not allowed to add more quantum numbers to the atom if the quants make the atom more accurate than the curvature of space. So, in the diagram, it is likely the blue bubble rotate opposite the orange because there must remain a 1/2 integer of imprecision. Coming straight out of the page, from the center, will be an axis having the twist, because of the torque called the wobble. The wobble, in turn, will induce the spiral, and the twist and spiral will be added to the quantums of wave motion, and become part of the internal packing of nulls.
These modes will define a symmetry for vacuum noise, a symmetry the identifies the direction of density curvature in free space. The symmetry will be sufficient for the free proton to navigate, so it and the other baryons can make the conditions that sustain the quasar. They do this by extending standing wave curvature across galactic scales, as if they were assisting gravity. That is my theory.
My guess is that there will be the spiral and the twist. Once I identify them, then I can rewrite them in terms of the Null (the green bubble), then go back to writing general wave motion in terms of hyperbolic single phase and null, where phase has been united into a single group.
I am likely to discover the quantums of symmetric wave between large and small bubble are already covered in the dipole physics. I will probably take a sneak and see if I can cheat a little, borrowing work already done.
Note: All motion is the action of a phase bubble exchanging with a Null. Be careful, everything is about phase exchanging with nulls in this theory and it is easy to fall back on the SpaceTime units of classical physics.
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