THE MALTA COSMOLOGY TEMPLATE

Chapter 7 - Electrons

PARTS

Part 3 - Cosmic Electrons (cont)

ARGUMENT 0715

• ARGUMENT 0712: The understable blackholes in a blackholepair are attracted to each other by their mutual gravitypull and repelled by their dense and extensive teelospheres. This is the “strong force” in action.
• ARGUMENT 0713: As the Universe expands, blackholes become sufficiently massive to endure but still unable to stabilise.
• ARGUMENT 0714: The structure of an unstabilised blackholepair is chaotic because its constituent blackholes are both centrifugally structured and therefore must tumble about each other in constant disorder.

• The default condition for any object is to be stable if conditions allow. Entropy is the tendency of unevenly distributed energy to become evenly distributed over time. A chaotic system will become less chaotic if less chaos is possible.

• Let the blackholepair consist of “blackhole A” and “blackhole B”.
• Each blackhole is centrifugally structured and thus has an equator and two poles – “pole N” and “pole S”.
• Each blackhole has an axis around which it revolves and which is a straight line from pole N to pole S.
• In a centrifugally structured blackhole, above the equator is a high pressure area of upward rising teels. Above the poles are low pressure areas of downward falling teels.
• In attempting to stabilise, a centrifugally structured blackhole ejects excess teels across its gravitysheath interface above the equator.

• For the blackholepair to stabilise, the following actions take place:

• The equator of blackhole A lodges against pole S of blackhole B.
• The axes of the two blackholes now form a T – with the axis of blackhole A being the vertical and the axis of blackhole B being the horizontal.
• This establishes a new teelstream in which teels move directly from the equator of blackhole A into pole S of blackhole B.
• This engorges the low level teelstream of blackhole B with energetic teels.
• This forces the equatorial upwelling of teels from the equator toward pole N.

• These actions change the structure of blackhole B from centrifugal to axial.
• The combined teelosphere of the blackhole pair and its constituent blackholes now operates thus:

• Excess teels exhaust from pole N of the axial blackhole, blackhole B.
• Those with enough energy will escape across the gravitysheath of blackhole B into the teelosphere of the blackholepair.
• Those without that much energy will curve their course to move along blackhole B toward pole S.
• Some will be reabsorbed by pole S of blackhole B.
• Others will cross the gravitysheath interface of blackhole B into the gravitysheath of the centrifugal blackhole, blackhole A.
• Those that enter the gravitysheath of blackhole A, do so above blackhole A's equator.
• Thus they plunge into the high level teelstreams which carry them to either pole N or S of blackhole A.
• At pole N or S of Blackhole A, the teels move downward to the low level.
• The teels now move at low level to the equator of blackhole A.
• At the equator of blackhole A, the low level teelstreams coming from poles N and S clash and are directed upward. 
• Above the equator of blackhole A, teels which do not have enough energy become the teelstreams moving at high level back to pole N or S of blackhole A.
• The teels which do have enough energy, escape across the gravitysheath interface of blackhole A into the gravitysheath of blackhole B.
• They arrive in the gravitysheath of blackhole B directly above pole S.
• They join the teelstream at pole S that is plunging down to low level.
• The low level teelstream moves directly from pole S to pole N of blackhole B.
• At pole N the teelstream climbs to high level.
• Excess teels exhaust from pole N of the axial blackhole, blackhole B.
• And the cycle repeats itself.
  

• In this way a continuous cycle is established with the teelosphere teelstreams of the two blackholes being as harmonised as they can be.
• The blackholes are now quarks, one centrifugal and one axial.

• The chaotic structure of a blackholepair is brought to order by the constituent blackholes becoming quarks, one axial and the other centrifugal.

• quark:   (1)  Any of a set of six hypothetical elementary particles together with their anitparticles thought to be fundamental units of all baryons and mesons but unable to exist in isolation. The magnitude of their charge is either two thirds or one third of that of the electron. (Collins World English Dictionary)  (2)  Quarks are the understable blackholes which are the principle constuents of electrons and nucleons. The understability of quarks is maintained by the stability of the electrons and nucleons they inhabit. Quarks can be axially or centrifugally structured. Electrons consist of one axial and one centrifugal quark. Neutrons consist of one axial and two centrifugal quarks.Protons consist of two axial and one centrifugal quark. When quarks are released from their electrons or nucleons, their understability means they promptly decay to photons, neutrinos, or blackholes - or they dissipate.