It is also the first point at which phase difference begins to matter. Up to this point, phase difference allowed the vacuum to maintain a slight space curvature with a slight swirl moment to define straight and to define the direction to the nearest quasar, but not much else.
Thursday, June 19, 2014
So Phi^17 must be the graviton?
Evidently so, it is the first, and barely stable loosely packed Gaussian ball of Nulls the vacuum makes. It fits with gravitational lensing, light would hit these things and go to the second Lagrange and split with two root solutions. Hit another one, and split again. These fuzzies would hang around, a tens of meters apart or so, and form real L1 spots in gravitational fields. All 3500 bubbles of Nulls and their Phase balls. Light would severely disperse these gravitons, but if space is otherwise stable, they would reform. These fuzzies have short wavelengths, in the third second moment, so the absolute zero experimenters at MIT can cool gravity. So, yes indeed, MIT did indeed freeze gravity.
It is also the first point at which phase difference begins to matter. Up to this point, phase difference allowed the vacuum to maintain a slight space curvature with a slight swirl moment to define straight and to define the direction to the nearest quasar, but not much else.
It is also the first point at which phase difference begins to matter. Up to this point, phase difference allowed the vacuum to maintain a slight space curvature with a slight swirl moment to define straight and to define the direction to the nearest quasar, but not much else.
Subscribe to:
Post Comments (Atom)
No comments:
Post a Comment