The
12th Planet’s Core
Planetary Dynamics of the 12th Planet
Scientists
who have been observing and studying the 12th planet on the remote
continent of Antarctica and the observatories located in Chilean Andes outside
of the public eye for the last 11 months, because of a southern approach to the
ecliptic plane have many questions. Starting with what processes are occurring
inside the core that can account for its rotation, internal production of
moderate heat & light, and intense magnetic & gravitational fields and
yet allow life to exist?
The
first feature is its variable period of rotation, a new concept, because the 12th
planet moves vast distances between both stellar objects in this binary star
system, the gravitational and repulsive forces that various parts of the core
are attracted and repulsed to in the universe change slightly. These forces
initiate the spin within the core as internal mass moves towards the target and
then overshoots, reinforcing its circular motion, which drives the inner core,
hence varying its rotational period. Presently the 12th planet
rotates slowly in a clockwise direction matching its orbital path around the Sun
and counter in direction to the Earth.
Contrary
to current theories, rotational momentum was not conserved from the Big Bang,
but the core of the 12th planet for now is on the move dragging the
crust of the planet until it cools billions of years in the future. The
rotational velocity of a planet is determined primarily by the core’s mass,
its compression, the torque with its equivalent force, the viscosity of the
liquid core, the frictional coefficient between the crust and the core, the
ratio of heavy elements to light, the percentage of iron or other elements
capable of magnetic properties, and the total mass vs. the average density, mass
and thickness of the crust. This is why the gas planets in this system with
their large planetary mass rotates rapidly, because their outer layers are
composed of lighter elements and a similar basic core contains a small amount of
heavy element mixed with compressed light elements, thus the torque load on the
core is lighter in relationship to the rocky inner planets. If you consider that
the terrestrial planets had to collapse in radii more than the gas planets when
coalescing. The greater differential in reduction of the radius of mass, the
greater the velocity of rotation, but observation shows us something different.
The
second feature, internal production of moderate heat and light has undone many
years of diligent work and the valued contributions of many gifted scientists.
The fusion process and minimum stellar mass for a light element compressed
cosmic object to light in our text books are all assumptions. Even though we
have a working example, the Sun little is known about its internal processes.
The
fusion reaction initiated by gravitational or total mass compression surrounding
the zone of reaction within the core, is correct. But, how do you contemplate a
fuel source with no dampener would be controlled and expansion balanced by your
definition of gravity as weak force, thus holding in check, the strong nuclear
force? The theory is incorrect.
Energy
production in the core of a cosmic object was first touched upon and explained
on an elementary level in the Fusion
Process, so lets add a little more detail. The process of sustained energy
production is initialized immediately after a localized Big Bang. The basic
determining parameters are: composition of the core, rate of mixing due to
forces surrounding the star, percentage of heavy elements that is magnetized,
the strength of its magnetic field across a defined cubic area, the average
amount of hydrogen nuclei in the compression zone, the average amount of mass
separating hydrogen undergoing reactions vs. replacement nuclei filling the
void, the ratio of the radius of the total core of heavy elements to the radius
of where fusion compression initiates, the mass of the core and the density of
the outer layers and its available mass, and finally gravitational forces
providing compression at the edge of the core.
To
examine the internal fusion process of a star, we will look at several phases in
the life of a star.
·
What causes a star to light?
·
When can this process occur?
·
Can a mass the size of our Sun fail to
light under certain conditions?
What
causes a star to light?
In order to grasp the total picture, I will examine the
precursors for a localized Big Bang before T = 0. After
a black hole forms, centered at what once was a galaxy that has been gathering
all available mass in a slow process, dark matter is captured first, next, the
small particles to asteroids, then moving to stray and stable orbital planets as
the gravitational field intensity balloons. Once the initial mass of the black
hole reaches a point to where the repulsion force of stars can not reverse
capture within the extreme gravitational field, the rate of expansion or mass
infusion into the core, thus mimics a hyperbolic curve. Absorption of stellar
matter and their related solar systems increases in proportion to the rate of
expansion of mass related to the black hole. So why does this process stop at
the edge of the galaxies instead of cannibalizing the entire of the universe?
This is where the repulsion force enters into the equation. Only small galaxies
with a total mass disproportionate to the main body (a ratio similar to a planet
and a large asteroid) allows stellar material to be stripped away from the
fringe areas until the total galaxy is consumed slowly for the largest to
immediate assimilation for the smallest on a universal time scale.
Inside the core of a black hole reveals some of the most intriguing mysteries of the universe. The Black Hole, with forces on a level beyond human comprehension are in a constant battle to balance the containment of the it’s core and the increase of total mass due to gravity. In the core, gravitational subatomic particles returning to mass responsible for the black hole overwhelms matter at the atomic level. The pressures due to crowding or influx of gravity sub atomic particles slow molecular motion to a crawl ( area of molecular vibration is reduced or contained in amplitude) and expansion due to heat the lubricant of molecular activity is controlled due to an ever increasing mass due to assimilation, halts outside expansion from built up internal pressures. Simply put the mass is growing at a faster rate than the by product, internal core activities, producing an intense gravitational field, which maintains a seal on the core as pressure and heat rises. During the final phases of the black hole, assimilation of new mass approaches a halt as all near by galactic resources basically dry up. The core under intense compression continues to expand until the now stable mass can no longer contain the outward momentum and a explosion or localized big bang initiates. Non homogeneous fragmented matter expands outward, with the first masses of the highest density and total matter tending to congeal earliest.
The
stellar formation process begins once a critical gravitational mass has been
reached, therefore initiating lighter elements to gather around the original
core. The random heavy elements captured continue to sink towards the central
core of heavy element where iron is a major component. Once enough mass has been
acquired, and in the case of a star where the composition of the outer shells of
the cosmic object is primarily a light element, hydrogen and in rare cases
helium, the compression of the light elements must move into a plasma ionized
state. In the case where a star lights, the primary property is that the core
must first have a magnetic field strong enough to charge the key hydrogen ions
and in extremely rare cases helium atoms to be attracted to the inner core by
magnetic attraction pulled along in bubbles composed primarily of hydrogen. For
a reference, we will start at the outside of the main heavy element core within
an unlit star.
As the core gathers mass related to elements that can maintain a magnetic charge, it activates hydrogen ions to adapt that charge near the poles of the core. Like charges repel and the hydrogen ions are pushed away from the poles that initiated the original charge. This separation of ions spreads around the core until the ions are pushed far enough towards the south pole of the core where forward attraction overcomes the local frictional forces. The breach of neutral movement plane (the neutral movement plane is the point where ions move in a specific direction as opposed to random motion) sets up a flow of the positively charged ions to the opposite pole, where they gather. Now the total flow of ions is dependant upon the density of the core and the polarity differential. The positively charged hydrogen ions due to pressures of crowding and gravity, the ions once in contact with the negative south pole first ground out. This produces a neutral charge and the adapts the negative charge of the south pole. Thus, moves towards, a charge adapted from the north pole of the magnetic core, penetrates the south pole of the magnetized heavy elements. The hydrogen ions, lighter than the surrounding core matter assumes the shape of a bubble and drifts towards the core driven by its charge that is attracted to the north end of the core. This is the key factor, because without the magnetic flow hydrogen ions would not be forced into the dense core of heavy matter. As random bubbles of hydrogen meet in the compression zone, pressure around the set of two ions must be equal on all sides as gravity induced compression fuses the two ions into a stable inert element of helium.
Now you are asking if the ions all have the same charge why don’t they
repulse? The core where mixing occurs adds a new twist. Some ions move to the
north side of the core and adapt over time a small positive charge. Random
movement keeps them near the core and by chance another ion which has not
grounded out or has retained its negative charge attract each other and with the
help of the force of gravity compression, the union is made. Helium with no
charge, but lighter than the surrounding mass floats slowly out of the core as
the newly formed atom is agitated towards the surface by molecular bumping.
Baffling
at first was how the fusion reaction responsible heat and stellar produced no
harmful radiation? Next, how the internal reaction was able to maintain its
steady energy levels when the planetary core was small in hydrogen reserves in
comparison to a star, since the 12th planet was here at the inception
of this solar system?
First,
in the interior of a fusion environment where compression is basically equal due
to many random interactions on the atomic level and time is almost factored out
of the equation, hydrogen atoms are fused naturally with minimal byproducts such
as harmful radiation, counter to the forced random fusion of atoms seen on
Earth. This concept is not new, just look to your environmental industries for
hints, but raise the efficiency a million fold and you still won’t come close
to the process. Now you will state, does the Sun not have deadly cosmic, gamma,
and X-ray bursts, which will harm mankind? Yes, but our atmosphere protects us
and astronauts survive in space during long term stays suggesting that the
effects may not be that extreme. You now must consider that a muted fusion
reaction within close proximity would produce the benefits of heat and light,
but may release little harmful radiation allowing life on a brown dwarf
functioning in the life zone to exist.
Second, the internal fusion reaction in the core of the 12th
planet from the model presently in the Sun is different in many ways. First, the
compression zone is much more compact, but compensates due to the heavier
elements that comprise this terrestrial planet with over 85 percent of its
surface covered with water. Second, its magnetic field is very intense for a
planetary mass. Third the charged ions moving into the core are elements outside
of the regular scope of hydrogen and helium. Thus producing a muted fusion
reaction due to a slower flow from heavier elements piercing the dense core of
the 12th planet and the fewer reactions occurring as like elements
find just the right conditions to fuse. The result a soft diffuse heat and light
production allowing life to thrive on a planet considered a brown dwarf. Do you
not think that nature has dampening factors to control fusion? If not, all stars
would super nova.
The
third feature is its magnetic field and why it has such far reaching effects?
The interior of the 12th planet is different than all planets in this
solar system. Not just in the fact a muted fusion reaction occurs, but the
content of iron based elements in proportion of other the heavy elements is much
larger than seen with other planets here. The effects of planetary magnetic
fields are little understood on Earth, because the magnetic fields of the Sun
and the other planets are in a state of equilibrium. So it can only be a new
unexpected interloper that may upset the balance. In a frictionless environment
it only takes a small force to tip a scale in balance.
When can this process occur?
Contrary to present day astrophysics, a star can only
light shortly after a big bang. This is not an on going process where a star
forms in what is considered stellar nurseries such as the present day gas
nebulas. The key is the composition of the core, gravitational compression and
the strength of the magnetic field, which initiates flow patterns of hydrogen or
helium ions through the core on the whole. All these parameters are set just
after a star’s mass congeals. If the fusion energy production is greater than
what can be absorbed by the total mass or radiated off without generation of a
significant production of photons, heat and light build and the star lights.
Otherwise a stellar mass will remain undetected by mankind except for the
gravitational perturbations created.
Can a mass
the size of our Sun fail to light under certain conditions?
If the star does not light in the beginning of a
localized big bang, it remains dark due to several primary reasons until its
capture by the galactic black hole. First, the heavy elements composing the core
maybe non magnetic in nature. So once all available hydrogen in the compression
region is fused, the mechanism for replenishment (magnetic subatomic particle
flow inducting a charge to hydrogen or helium ions) is frozen. The star may
light in rare occurrences for a relatively short period for stellar evolution
and just wink or sputter out. Second, the core is magnetic in nature and a flow
of fuel is sustained, but the dampening rate of the heavy elements on the
extreme end, which reduces the fusion process and the energy released to a point
where the total mass absorbs all of the radiant energy. It is that lower middle
ground that takes us to the next subject, the Brown Dwarf.
Where does
a Brown Dwarf fit into stellar evolution?
Mankind
and his science has always been fascinated by the theory of absolutes, a number
that states this is final. One the biggest flaws is absolute zero, a theoretical
point where all molecular motion stops, on the other side activity on the high
end approaches infinity, example is the entire mass of the universe expanding
from a singularity. Why is there a contradiction? This is a mystery mankind will
never solve, there will always be some type of motion no matter how small.
Molecular motion will always approaches zero, but will never get there. The more
refined your instruments get and the more heat you remove from a controlled
space the more you will find subtle activity. The better the resolution your
telescopes achieve, the further you will push back the age of the universe. Let
your curiosity and intellect that has lead you the propose so many theories that
have worked under present conditions consider they may not work in other areas
of the universe. I believed in them at one time and some still now, all is not
wrong. Start fresh with a new slate as if you have learned nothing about the
universe, with your methods of research intact you will do just fine in the
transition. There are many new discoveries to be found, the quicker the base is
corrected the faster you will achieve new heights in the many fields affected.