What is Expansion

A General Theory of Relativity should predict that a local universe is not static, as observations confirm this, indicating that it is expanding.
It must be remembered that the Big Bang represent the creation of a minor universe.
This event marking a beginning suggests, the minor universe must have been much smaller at its inception.

The Big Bang should be pictured as a big explosion somewhere in space with fragments being cast out omni directional from an exploding mass, known as the Big Bang,
This does not mean that the galaxies and lesser objects are flying out into space infinitum, the fact is, relatively very few bodies do, eventually galaxies lose all velocity. As temperatures decrease, planets, stars, galaxies evolve and acquire spin, orbit and adopt a buoyancy state, as matter at rest. What it does suggest is, matter in space is becoming dispersed, diffused, spread out and in so doing, it increases fundamental particle content in space and the distance between celestial bodies.

How does this effect man? We are living in the most intriguing time, in a universe like nothing we imagined just a few short years ago. A hypothetical such as, is man expanding or contracting by some mysterious force were curiosities of fiction. Living organisms are not noticeably subject to this phenomenon of universal expansion; the dark matter (DM) permeating our body is of higher thermal value in comparison to DM in space.(ok so!). Our planet is continuously and simultaneously supplied and depleted of thermal energy, contraction will effect matter of the higher thermal content first and translate as a decrease in fmp* structure (diameter) and specific* particle content.

Here we may apply the Second Law of Thermodynamics.

This law claims that "Energy spontaneously tends to flow only from being concentrated in one place to becoming diffused or dispersed and spread out".
As long as our planet compensates our thermal value, we will not feel any noticeable effect , and dark matter will absorb energy from the higher thermal emitting matter (E.g. galaxies, stars, earth etc.).

When considering universal expansion we can only observe what we can see. Suppose we observe the stars in the outlying universe, and suppose we observe idiosyncratic mannerism of everyday matter, can we structure common inherent properties.

Assuming the universe, galaxies and all the matter on earth are permeated * by dark matter particles, can these idiosyncratic phenomenon in possession of these structural and behavioral characteristics apply a logical postulate?

There is a consensus in the astronomical community that most of the mass in most galaxies is non-luminous dark matter and those celestial objects in space and matter on earth are analogous.
I refer here to Dark matter as a generic term for these fundamental particles in the universe though not directly observable, they do permeate all matter and fill all space with their presence as inferred by the motion of galaxies.

Dark Matter particles absorb contiguously and omni - directional thermal information from higher energy sources (e.g.stars).
Hypothetically one may extrapolate an increase in thermal content will increase the structure of the fundamental particles (DM) likewise increase the content of specific particles in the region and interpret this as increase in the local universal volume.

If this assumption is valid than our Sun's thermal information (energy) lose, should express a constant increase to earth's orbit.

fmp * = fundamental particles (The term "fundamental particle" is used here to avoid having to invent new terminology)

permeate* = 1 The fmp- form a 3 dimensional geometrical lattice, isometric, homogeneous, permeate and immerse all matter and assist to define the magnitude of the universe with their volume inflation.
Permeate* = 2 The neutral fmp is instrumental in the construction of a plasma; neutral particles must rest in an adjacent formation. Sequentially vast quantities of contactual neutral particles are needed to simply fill the volume and implement a route for universal thermal transference.
Specific particles* form baryon matter.

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