LIGHT

"The electromagnetic spectrum (E-M) is the range of all possible
frequencies of electromagnetic radiation. The "electromagnetic
spectrum" of an object is the characteristic distribution of
electromagnetic radiation emitted or absorbed by that
particular object.

The electromagnetic spectrum extends from low frequencies used
for modern radio to gamma radiation at the short-wavelength end,
covering wavelengths from thousands of kilometers down to a
fraction of the size of an atom. The long wavelength limit is
the size of the universe itself, while it is thought that the
short wavelength limit is in the vicinity of the Planck
length, although in principle the spectrum is infinite and
continuous."
http://en.wikipedia.org/wiki/Electromagnetic_spectrum

"Light or visible light is the portion of electromagnetic
radiation that is visible to the human eye, responsible for the
sense of sight. Visible light has a wavelength in a range from
about 380 or 400 nanometres to about 760 or 780 nm,[1] with a
frequency range of about 405 THz to 790 THz. In physics, the
term light often comprises the adjacent radiation regions of
infrared (at lower frequencies) and ultraviolet (at higher),
not visible to the human eye."
http://en.wikipedia.org/wiki/Light

"The atom is a basic unit of matter that consists of a dense,
central nucleus surrounded by a cloud of negatively charged
electrons. The atomic nucleus contains a mix of positively
charged protons and electrically neutral neutrons (except in
the case of hydrogen-1, which is the only stable nuclide with no
neutrons). The electrons of an atom are bound to the nucleus by
the electromagnetic force. Likewise, a group of atoms can remain
bound to each other, forming a molecule. An atom containing an
equal number of protons and electrons is electrically neutral,
otherwise it has a positive charge (electron deficiency) or
negative charge (electron excess) and is an ion. An atom is
classified according to the number of protons and neutrons in
its nucleus: the number of protons determines the chemical
element, and the number of neutrons determines the isotope of
the element."
http://en.wikipedia.org/wiki/Atom

In the AV model, the concern is with the source of light as it
pertains to the three sizes of Shells: Large, Small, and
Smallest, or Atom, Neutron, and subNeutron. Light in this
article pertains to two spectrums.

ATOM

Questions
Imagine a standard model of a simple Hydrogen atom. There is
a neutron at the center and an electron in orbit. Remove the
neutron and ask where is the energy in Einstein's E=mcc? How
did this atom, electron and neutron
originate? Where will they end?

In the AV model, a Shell is a set of interlocking fields.
Imagine a small bar magnet and let it rotate so fast that the
North pole and South pole are at the same place. Let this bar
magnet rotate in all directions. Its surface looks like uncut
pile. When one touches something, one feels these piles and
not an electron in orbit. These Shells formed before the
Big Bang and will return to Space eventually.

In the AV Hydrogen atom, there is a small Shell inside a
normal Shell, i.e., a neutron inside an atom. The center of
this atom is where the incoming lines of Gravity convert to
expanding spheres of Space. Some incoming lines of Gravity
convert to Linear motion as mentioned above. It also
appears that a small amount of this incoming Gravity
converts to Ray. This Ray goes to surface of the atom and
converts to Space. Gravity converted to Ray during the
compression period before the Big Bang, and this appears
to be a carryover from that period.

As Ray converts to Space at the surface of the normal Shell,
it creates a local disturbance. As Ray rotates within the
atom, this disturbance also appears to rotate. This surface
disturbance is what one calls an electron.

The electron is negative because the viewer is outside the
atom, i.e., the Ray is on the other side. As this Ray passes
through the neutron, the viewer is on the same side as Ray.
In this case, the neutron has a positive disturbance and
is known as a proton.

NEUTRON

Let the neutron process its incoming Gravity in the same
manner as the atom. The difference is that the surface of
the neutron is not in contact with the local Space. It is
in the atom where there is a high density of other fields.
In this case, the Ray doesn't convert to Space, but it
converts to a point about which oscillate the fields of
Electro and Magno. This type of conversion also occurred
during the compression period.

Notice that there is no Linear motion associated with
this point. It is a point of light without any associated
mass. This photon rides outward on the expanding spheres
of Space like a surfer riding a wave into a beach. As it
moves into deep Space, it loses its energy and eventually
becomes a point in Space.

subNeutron

Now assume a subHydrogen atom. It has a subNeutron in a
neutron. Let this subNeutron process its incoming Gravity
in the same manner as the atom. The difference is that
the surface of the subneutron is in the neutron where
there is a very high density of other fields. In this
case, the Ray doesn't convert to a point of light in the
E-M spectrum. It converts to a point about which
oscillate the fields of Kone and Magno. This is the dark
light (D-L) spectrum. Our eyes did not evolve to see
this light so it appears black.

It is possible to have a neutron star that is large and
black. This is not a black hole. A black hole is a
collection of many subNeutrons which reconvert all
incoming materials to Space.