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Darkmatter Selfproofs |
SELFPROOF 0503
– UNDUE DENSITY OF MERCURY
CURRENT COSMOLOGY MODEL
Mercury's
density is the second highest in the Solar System at 5.427g/cm3,
only slightly less than Earth's density of 5.515g/cm3. If
the effect of gravitational compression were to be factored out, the
materials of which Mercury is made would be denser, with an
uncompressed density of 5.3.g/cm3 versus Earth's 4.4g/cm3.
Mercury's
density can be used to infer details of its internal structure.
Although Earth's high density results appreciably from gravitational
compression, particularly at the core, Mercury is much smaller and
its inner regions are not as compressed. Therefore, for it to have
such a high density, its core must be large and rich in iron.
(Wikipedia 04 June 2013)
MALTA COSMOLOGY TEMPLATE
- Every
blackhole in the Universe is within the gravitysheath of a larger
object. (see Argument 0336)
- Many blackholes are within the teelospheres of larger objects.
(see Argument 0337)
- Blackholes absorb teels from the teelosphere they are within which
alters the blackhole's measures of mass and energy. (see Argument 0338)
- A
stable blackhole within the teelosphere of a larger object becomes
understable due to the differential absorption of mass and energy
from the teelosphere. The stability of already overstable or
understable blackholes alters commensurately. (see Argument 0339)
- A
stable blackhole within a teelosphere, made understable through the
differential absorption of mass and energy, ejects more than it
absorbs until it returns to stability. The stability of already
overstable or understable blackholes alters commensurately. (See Argument 0340)
COMMENTARY
- Quarks
are blackholes and consist of a solidbonded teelcore, perhaps a
teelocean, and a teelosphere.
- Nucleons
consist of three quarks of two different types, axial and centrifugal.
- Atoms
consist of nucleons in combination.
- Thus nucleons
and atoms consist of a core of blackholes surrounded by a
teelosphere.
- Quarks,
nucleons and atoms, when solidbonded to others of their ilk, are
held together by gravity and held apart by their teelospheres.
- The
planet Mercury consists of a core of solidbonded atoms surrounded by
a teelosphere.
- In
the Malta Cosmology Template the one pecent rule equates to objects
being ninety nine percent gasbonded teelosphere and one percent
solidbonded teelcore.
- Thus
the atom core of planet Mercury consists of 1% teelcore and 99%
teelosphere.
- Except
that it doesn't because the orbit of Mercury is within the Sun's
upwelling teelospheric disc.
- This
puts it within a dense and fast moving teelstream surging upward
from the Sun's equator.
- This
has two effects.
- The
first is that teelstream teels strike the teelcores, exchanging
spinspeed and thus pushing Mercury outward and precessing its orbit
(see Selfproof C0502).
- The
second is that the teels that don't strike the teelcores, either
pass right through the planet or they strike teels in the
teelospheres.
- If
they strike the teelosphere teels there is an exchange of spinspeed
which entropically raises the vergence velocity of the teelosphere.
- If
the teelstream is fast enough and dense enough it will raise the
vergence velocity of the teelosphere above the escape velocity of
the planet.
- The
effect of this is to reduce the rejectivity of the teelospheres of
Mercury's atoms.
- The
effect of this is allow the atoms to “rest” closer to each
other.
- The
effect of this is to increase the density of the planet because a
given number of nucleons can occupy a smaller area.
- The
current explanation is that Mercury has a core rich in iron and this
may be so - increase the packing density of atoms sufficiently and
heavier atoms are formed out of lighter atoms (see Chapter 9 Atoms and Chapter 10 - Atom Mechanics).
- Nevertheless, at least some of some of Mercury's undue density is due to its
position within the Sun's teelosphere.
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GLOSSARY
- one percent rule:
The rule of thumb: ninety nine percent of the
matter in an object occupies one percent of the object's volume.
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