Gravimagnetics continues to slowly evolve, as I dunder and blunder my
way along, especially from page 28 to 33:
http://mtaonline.net/~hheffner/FullGravimag.pdf
Some snippets of fairly new material follows.
There is a seeming problem regarding the conservation of
gravitational charge. Matter-antimatter pairs created from the
vacuum carry the same gravitational charge. Gravitational charge
thus appears to not be conserved. There is a convenient and highly
unanticipated resolution to this problem. When a matter-antimatter
pair is created from the vacuum there is always simultaneously
created a mirror matter-antimatter pair. Call such a foursome a
*dual pair*. Further, having negative gravitational charge, the
mirror matter-mirror antimatter pair represents negative energy.
Thus is provided a significant new interpretation of the Dirac
equation negative energy. Further, the net energy created from the
vacuum double pair formation (initially anyway) is stunningly exactly
zero. ...
In normal (weak field magnitude) circumstances, when it comes to the
flat space Dirac equation, the interaction Hamiltonians, etc., the
gravitational universe, consisting entirely of imaginary quantites,
can be viewed as completely independent for computational purposes,
and then consolidated. The exact same equations can be applied to
the gravitational portion of the computation in order to derive the
gravitational forces, energies, waveforms, etc. The gravitational
formulations are completely independent of the electromagnetic
formulations. They are isomorphic, so the same equations are used,
though with the isomorphism substitutions as defined. The results,
however, are not similar in handedness or magnitude, because, though
the equations are all formally identical, there are imaginary values
coming into play, and h_g = - h, G is used instead of the Coulomb
constant, etc. Because the gravitational charge and EM charge are
bound together, the forces can be summed to characterize a fermion,
or to characterize a boson-fermion interaction as a whole. The
Hamiltonians exist independently and energy conservation results in
both universes. ...
Note that any sized black hole with mass occupying a point has, for
some finite radius, a volume in which the field strength is
sufficient for double pair creation to take place. As the mass of
a black hole increases, the radius of this mass spawning sphere
increases. For this reason, essentially every black hole spawns
mass from the vacuum, and thus simultaneously builds its own mass.
Also for this reason, spawning black holes, using the Large Hadron
Collider, for example, may be far more dangerous than anyone
expects. ...
BLACK HOLES RADIATE
Black holes consisting of mirror matter create dual pairs, as
described above, and absorb the negative gravitational energy of the
mirror pair. The real pair is then ejected in one form or another,
either as a matter pair, or as a pair of real photons. Analogous
effects occur from real (as opposed to mirror matter) black holes.
The smaller the black hole, the greater the proportion of energy
ejected that should be in the form of photons. In any case, most of
the mass-energy ejected should be in the form of photons due to the
high probability of (like gravitationally charged) pair
annihilation. These gravitationally emitted photons will have energy
levels that indicate the (positive) gravitational potential of the
radius at which they were formed. Further, the radiant mass-energy
of a mirror black hole not feeding on other bodies provides a direct
indicator of the rate of mass increase of that black hole due to dual
pair creation, because the two mass-energy flow rates are equal.
This radiant energy is *not* Hawking radiation. Its origin is not
the event horizon, but rather the interior of the black hole, and its
spectrum provides information about conditions inside the black hole,
including its mass and the dual pair formation flux at various radii
r. Negative gravitational matter is utterly unaffected by an event
horizon. Dual pair initiated radiation is comparatively invisible
when coming from an ordinary matter black hole because the radiation
is mostly mirror radiation.
Horace Heffner
http://www.mtaonline.net/~hheffner/
