Newton's Shell Theorem is found to give us an elegant shortcut to the truth.
A significant but seemingly paradoxical effect takes place
within a planet or star endowed with a negative charge. Such charge is
demonstrated by the deflection of comets’ tails from the sun and the exothermic
rise of electrons from Earth’s surface. The excess electrons scatter themselves
as far apart as they can get by surrounding the hosting body, arrayed as a
bubble formation. Yet, by doing so, they impart their collective electrical
force into the central core of their host where as a consequence, not a single
particle of that polarity of electric charge resides. Hence, in accordance with
Newton’s Shell Theorem, negative particles upon the outside surface transfer
their influence to the center of a negatively charged body. This virtual charge
causes continual migration of protons inward and electrons outward without
affecting the magnitude of the central virtual charge that pulls a core of
mingling protons together. Such a core can provide conditions for a static form
of nuclear fusion that would augment energy produced from dynamic fusion to be
found in surrounding plasma, but necessarily without any destruction of
electrons. Such a virtual electron generation process within billions of
stars implies a growing negative cosmic electric charge and perhaps a decent
explanation for anti-neutrino shortfalls.
The Shell Theorem converts well enough to a Rim Theorem
whereby all of any excess particles of electric charge would center a virtual
equivalent combined charge of the same polarity upon the rotational axis of the
disk. Such a virtual charge would call particles of the opposite charge into
the same location. That is how polar jets work: Negative charge on the rim of a
protoplanetary disk results in the ejection of positively charged matter from
the rotational poles of the protostar, and positive charge on the rim of a
black hole’s accretion disk results in alignment of electrons along the
rotational axis of the black hole’s accretion disk. In the latter case, mutual
repulsion of the aligned electrons accounts for outward acceleration of
electron beams.
