THE MALTA COSMOLOGY TEMPLATE

Chapter 7 - Electrons 

PARTS

Part 1 - Kickstarter (cont)

ARGUMENT 0702

• ARGUMENT 0701: Electrons have a structure. 

• In specific conditions, so far as is known, all electrons have the same measures.
• Objects made out of teels that all have the same measures in specific conditions must have a mechanism and/or process to maintain those measures.
• Following on from the above, there are four options:

• OPTION ONE: An electron is a single stable object made out of numbers of teels.

• A single stable object made out of numbers of teels is either a blackhole or a specialised form of blackhole such as a photon.
• Blackholes have a mechanism that automatically moves them toward stability or maintains them at stability. However the mechanism establishes stability at no specific mass and once a blackhole is stabilised, its mass can change while stability is maintained.
• Photons are stable as long as they are within photonic masses. However, the mass of photons can alter within the photonic masses without any loss of stability.

• Currently, there can be no certainty that electrons are not single objects made out of numbers of teels. However there is no readily apparent mechanism/process that will maintain an electron's consistent measures. And if the electron is actually an overgrown photon, there is no readily apparent mechanism/process that will give it a measure of charge.

• OPTION TWO: An electron is a stable object consisting of a pair of gravitationally bound objects with each being made out of numbers of teels.

• An electron consisting of two objects fits satisfactorily into the “universe graphic” (see “Summary of Findings”) as a “blackhole composite”. The other options do not.

• This chapter illustrates that a pair of objects, subject to specific starting conditions, will evolve into an object that behaves like an electron and has the measures of an electron.

• OPTION THREE: An electron is a stable object consisting of three gravitationally bound objects with each being made out of numbers of teels.

• A trio of gravitationally bound objects, subject to specific starting conditions, will evolve into an object that behaves like a nucleon and has the measures of a nucleon (see Chapter 8).
• There is no readily apparent mechanism/process that will evolve a trio of gravitationally bound objects, no matter what the starting conditions, into an object that behaves like an electron and has the measures of an electron.
• Overstable/understable nucleons (see Chapter 8) stabilise by ejecting teels and/or blackholes (neutrinos) and/or electrons. There is no readily apparent mechanism/process by which a nucleon can stabilise by emitting a further nucleon.

• While the notion of an electron being composed of three gravitationally bound objects cannot be discounted until it is possible to inspect the internals of an electron, it seems unlikely.

• OPTION FOUR: An electron is a stable object consisting of four or more gravitationally bound objects with each being made out of numbers of teels.

• In the Universe there are many objects which consist of four or more gravitationally bound objects. However, their binding is always indirect. A helium atom is composed of four nucleons but the nucleons are themselves composed of three quarks and a number of electrons. A star is composed of a great many gravitationally bound objects but those objects are atoms – which are of course composed of quarks.
• In theory there is no reason why objects consisting of four or more directly-bound lesser objects should not evolve. However the starting conditions for such evolutions are extremely rigorous and, since such objects have never yet been found (or even hinted at) it is reasonable to suppose they have never existed in the Universe in its current evolutionary cycle.

• The notion that an electron is composed of four gravitationally bound objects is highly unlikely.

• There is as yet no empirical evidence supporting any of the options but, in the light of the conclusions and assumptions of earlier chapters, Option Two seems the most likely by a margin so considerable that the other options seem improbable.
• The prior candidacy of Option Two is reinforced by the way it does not clash in any way with the evolutions of subsequent chapter.
• Given the current lack of empirical evidence supporting Option Two, the other options should not be dismissed as yet. One of the lessons of history is that outsiders can win – so there is value in considering the other options further.

• NOTE: Although they are probably indistinguishable from one another, electrons come in two types. There are cosmic electrons or stabilisation electrons. Cosmic electrons formed soon after Moment Zero. Stabilisation electrons are formed during the stabilisation of nucleons.

• An electron consists of two gravitationally bound blackholes.

• cosmic electron: An electron that formed soon after Moment Zero due to the expansion of the Universe. (See also stabilisation electron)

• photon: A centrifugally structured blackhole which has stabilised within the photonic masses and at lightspeed.

• photonic masses: The range of masses of photons, from low mass photons with a wavelength of 100Mm or more to high mass photons with a wavelength of 1 pm or less. In the Current Cosmology Model, photons are massless and defined by their wavelength, frequency or energy. For simplicity, The Malta Cosmology Template identifies specific photons by wavelength.

• Stabilisation electron: An electron that forms during the stabilisation of nucleons. (See also cosmic electron)