Version 1: Modified 3/28/09
Version 2 Modified 6/6/09
We have alluded to the positive core of stellar bodies, and will get back to that in a later post. Letting it suffice to describe stellar fusion as an issue of positron depletion, we borrow credence that shining galaxies bear an excess of electrons. Hence, systemic traction for charged particles in shining stars and in outer portions of shining galaxies is outward for electrons and inward for particles of positive charge. There is no escape for such positive particles from an active galaxy. They descend to an ever-increasing accretion disk which has become an orbiting body of protons whirling around a super massive black hole that was nothing more than the center of gravity for the disk in the first place, or of the sphere that the disk had been at the time.
Beneath the rim of this accretion disk lies a domain of dark matter by virtue of regional positive majority charge: systemic traction strives to elevate particles of positive charge and to drive electrons down to the rotational axis. At any elevation within the disk, a proton holds its radial position in part from centrifugal force and in part from electrostatic repulsion. Protons at the rim of the disk are at electrostatic rest, held aloft from the black hole by its transverse velocity ergo centrifugal force. Protons gain displacement down from the rim as kinetic energy converts to virtual electrical charge under the influence of descending electrons sweeping across the orbital proton paths. Positive ionic density tapers down with descent due to increased electron density brought on by convergence.
As the accretion disk continues to grow, its rim intervenes upon any neutral matter such as to be found in stellar systems or dust in orbit around the singularity, to rip away electrons with its severe electrostatic traction. It thus showers the protons below with momentary neutralizations as perhaps they take an occasional encirclement. During such neutralization of a proton at any given level, it has lost its electrostatic share of lift, to fall a tiny way before re-ionization. Thereby, kinetic energy has given way to increased storage of electrical energy as the proton finds itself driven farther from its quest of the rim. Each such incident steps the proton to lower radial position on the disk and to a reduced velocity. Given the influence of a sufficient unrelenting wash of descending electrons, a proton could be driven as far down as the event horizon, or anywhere between. The overall result is a smearing of proton wind that confounds orbital suspension for heavier particles to be conveyed into the event horizon. When "feeding time" is over, the charged portion should thin down and stretch out as though a casted noose extending out in pursuit of more distant star systems. After roping another victim, a new supply of descending electrons spreads the disk out to filter more food into the black hole, and the galaxy gets reamed out some more.
No such rigmarole impedes the fall of any neutron-bearing atom. The crowd of protons poses an atmospheric resistance for any other atoms, serving to winnow any other substance into the event horizon except for separate electrons with their stated immunity. The accretion disk thus conveys all other matter into the black hole, but hoards its protons until they can eventually nullify or overturn the negative galactic majority charge.
We seem to have blundered into seeing how black holes can grab stars that seem safely hidden far away in orbit. Meanwhile, about those electrons laid down onto the extended rotational axis of the accretion disk: they repel away along that axis under extreme control of a very large focusing anode whereby the resulting beam maintains equidistance from all around the mean effective electrostatic circle of the disk. The columns of electrons departing from a point short of the singularity might offer imperative escape paths for mounting temperatures of convergence, and momentary endothermic emergence of positrons could provide for timely explosive energy dispatch outside of the event horizon.
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