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PART 1 – CENTRIFUGAL BLACKHOLES

CONCLUSION 0501 - Every teel in a blackhole's teelcore, no matter what its position, takes the same average time to complete one orbit around a spinning blackhole's axis.
CONCLUSION 0502 - In a spinning blackhole teelcore, the teels at the equator have the greatest totalspeed and those at the axis have the least.
CONCLUSION 0503 - The spin of a blackhole's teelcore is echoed in the spin of its teelosphere with the teels above the equator having the greatest totalspeed and those above the poles having the least.
CONCLUSION 0504 - Any acceleration in a teelosphere teel equates to a movement toward the equator and a deceleration equates to a movement toward the poles.
CONCLUSION 0505 - Teels in a blackhole's teelosphere stratify in altitude and latitude according to their realspeed relative to each other with the fastest low over the equator and the slowest high over the poles.
CONCLUSION 0506 - The default flow pattern for a blackhole teelosphere is centrifugal with low level teels streaming toward the equator and high level teels streaming toward the poles.
CONCLUSION 0507 - In a centrifugal blackhole, the principal point for the ejection of teels across the gravitysheath interface is the teelospheric equator.

COMMENTARY – Some blackholes have axial teelospheres where their teels stream from one pole to the other. However axial teelospheres result from external influences and in the absence of such influences, the teelosphere of a blackhole is always centrifugal.

The centrifugal flow pattern is not unique to the teelosphere of a blackhole. It can be seen in any accretion of gas or liquidbonded objects bound into the gravitysheath of a spinning larger object. Thus, Planet Earth's gasbonded atmosphere and liquidbonded oceans are overall centrifugal even though their complexity often makes them appear not to be so.

PART 2 – AXIAL BLACKHOLES

CONCLUSION 0508 - Every teelosphere consists of teelstreams, each of which has its own direction, speed, and density.
CONCLUSION 0509 - Every teelosphere is influenced by the direction, speed, and density of the teelstream through which it is moving.
CONCLUSION 0510 - Every blackhole moving through the teelstreams of a larger object has a teelospheric northpole which is the principal absorption point for teels into its teelosphere.
CONCLUSION 0511 - When the speed and density of a teelstream is sufficiently dominant, it forces the teelospheric equator to be at 90 degrees to the teelospheric northpole.
CONCLUSION 0512 - When the speed and density of a teelstream is even more dominant, it forces the teelospheric equator away from the teelospheric northpole toward the teelospheric southpole to make the blackhole semiaxial.
CONCLUSION 0513 - When the speed and density of a teelstream is even more dominant, it forces the teelospheric equator to the teelospheric southpole and makes the blackhole axial.

COMMENTARY – An axial blackhole is unstable in that it cannot endure outside a dense and speedy teelstream. Such conditions are found in composite objects, specifically in twin quark composites (electrons, etc) and triple quark composites (protons and neutrons). Chapters 7 and 8 cover the subject in detail but in essence:

Quarks are blackholes which are gravitationally bound accretions of teels.
Quarks are found only in twin and triple composites.
Quarks decay into photons if their home composite is broken up.
Quarks endure in composites as a mix of centrifugal and axial blackholes.
Twin composites are one centrifugal and one axial blackhole.
Neutrons are two centrifugal and one axial blackhole.
Protons are one centrifugal and two axial blackholes.
What is conventionally identified as a quark is actually its teelcore.
What is not seen is its dense and speedy teelosphere.
In the Current Cosmology Model, quark behaviour is atypical in that quarks are bound to each other by the strong force but that at a specific distance apart, the strong force becomes repellent.
Quark composite behaviour is that each quark teelcore is gravitationally bound to its partner(s) but none can approach its partner too closely because if its teelosphere. Like a ping-pong ball on a fountain, each blackhole rides on the teelosphere of the other.

An axial blackhole is “charged” and a centrifugal blackhole is “neutral”. This effect in a second hand form is passed on to the quark composite particles. Thus twin composites like electrons are charged particles, neutron triple composites are neutral particles, and proton triple composites are charged particles. They are charged or neutral because each has its own teelosphere, over and above that possessed by the quarks and those teelospheres are either axial or centrifugal.

The effect is further passed on to the nucleon composites: the atoms. These too have teelospheres which can be axial or centrifugal (although as is seen in chapters 9 and 10, the complexity of these particles means that their teelospheres are likewise complex, often having both axial and centrifugal aspects. In atoms it is axiality which at the root of the ability of some to conduct electricity and others to be magnetic.

PART 3 – TEELOSPHERES AS DARKMATTER

CONCLUSION 0514 - In a blackhole, the teelcore's gravitypull acts on the teelosphere and the teelosphere's gravitypull acts on the teelcore.
CONCLUSION 0515 - A smaller object within the teelosphere of a larger object is subject to the gravitypulls of the larger object's teelcore and its teelosphere. Depending on where the smaller object is within the teelosphere of the larger object, the gravitypull of the teelosphere weakens or strengthens that of the teelcore.

COMMENTARY – The darkmatter effect is caused by the teelosphere surrounding a teelcore. In an understable object, the teelosphere can be substantial and extensive. The Milky Way galaxy is an understable blackhole, the teelcore probably being Sagittarius A, with its teelosphere possibly extending out to the gravitysheath interface. That the teelosphere has a substantial gravitypull is observed in its effect upon the stars in the galaxy disc.

That most blackholes have teelospheres is apparent even in objects not readily perceived as blackholes. The Sun is an example of this. It is not a blackhole but it has a teelcore of a sort. It is composed of atoms which are in turn composed of quarks which are blackholes (see Chapter 9). Thus the Sun has a “composite” teelcore which is in turn surrounded by a teelosphere. The darkmatter effect is observed in the effect of the Sun's teelosphere on the orbit of the planet Mercury.

PART 4 – SELFPROOF

SELFPROOF 0500 - SELFPROOF HOME
SELFPROOF 0501 - DARKMATTER
SELFPROOF 0502 - PERIHELION PRECESSION OF MERCURY
SELFPROOF 0503 - UNDUE DENSITY OF MERCURY
SELFPROOF 0504 - STARS AT A GALACTIC CENTRE
SELFPROOF 0505 - GLOBULAR CLUSTERS

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Chapter 1 - Fundamentals | Chapter 2 - Moment Zero
Chapter 3 - Blackholes | Chapter 4 - Darkenergy
Chapter 5 - Darkmatter | Chapter 6 - Photons
Chapter 7 - Electrons | Chapter 8 - Nucleons
Chapter 9 - Atoms | Chapter 10 - Atom Mechanics
Chapter 11 - Stars | Chapter 12 - Star Mechanics
Chapter 13 - Galaxies | Chapter 14 - Galaxy Mechanics
Chapter 15 - Galactic Clusters
Chapter 16 - Galactic Cluster Mechanics