Critical Compression (CrC)

Critical Compression refers to the moment when Ultrons (www.101123.com/U) become atoms.

Critical Compression manifests as Quasars and Gamma-ray bursts depending upon the amount of torqued mass involved.

Critical Compression is the boundary between the Congeneric Realm of Propagation (www.101123.com/CRR) and the Congeneric Realm of Dissipation (www.101123.com/CRR).

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What causes critical compression? What causes the transition from propagation and dissipation?

What causes critical compression?Quanta are continuously emerging and expanding as they decelerate with each pulse. The Universe is finite; therefore, the existing quanta are compressed "inward" as their outer ellipsoidal "envelope" becomes more spheroidal with each pulse.

There is a point/moment when the internal motion is so compressed that it can no longer be contained within the quantum/Pulsoid. The resultant phenomena of this Critical Compression are the atom and Dissipents including photons.

Critical Compression is observed as quasars/proto galaxies and gamma-ray bursts.

What causes the transition from propagation and dissipation?Compression of fermions in accordance with the Pauli Exclusion Principle (www.CQthus.com/PT/PEP) (PEP).

In what way does the Pauli Exclusion Principle relate to compression of fermions? The principle merely states that no two electrons can have the same quantum states.

In what way does the Pauli Exclusion Principle relate to compression of fermions? The principle merely states that no two electrons can have the same quantum states."...no two electrons can have the same quantum states." Thus, they must compress, rather tnan coalesce in the manner of bosons, when they are "pushed" together.

The Pauli Exclusion Principle (PEP) states that no two fermions (particles of mass) can be in the same place at the same time, unlike light waves, (bosons). As more fermions emerge into a finite Universe, there must be compression.

It can be said that quasars and gamma-ray bursts are the proof of a finite Universe.

There is a point/moment when the internal motion is so compressed that it can no longer be contained within the quantum/Pulsoid. The resultant phenomena of this Critical Compression are the atom and Dissipents including photons.

Before the critical point, does the internal motion manifest as "dark" or "transparent" energy? What does the boundary of a pulsoid consist of, and what prevents the energy from escaping?

Before the critical point, does the internal motion manifest as "dark" or "transparent" energy?Yes. That is, the entire quantum/Pulsoid (www.CQthus.com/PT/P)/"dark" matter (www.CQthus.com/PT/DM) is the essence of "space," the Dyosphere (www.Dyosphere.com).

What does the boundary of a pulsoid consist of, and what prevents the energy from escaping?The boundary, the extent of the energy, is determined by the pulse, which is a function of the Conceptual Unit (www.CQthus.com/PT/CU) (CU) that is heuristically defined by the Elliptical Constant (www.CQthus.com/PT/EC) (EC).

So then, if all space is quantized, what differentiates the matter which is "seen" and "felt" from the "dark" matter? Does the internal geometry differ?

So then, if all space is quantized, what differentiates the matter which is "seen" and "felt" from the "dark" matter?"Dark" matter (www.CQthus.com/PT/DM) (DM) is felt; its effects are observed. It just does not emit photons. Its effects are obvious in the motion of the stars within galaxies; and, of course, you see its compression every time you "drop" something. And, DM compression's reaction effect is what is observed as accelerating, galactic recession.

Does the internal geometry differ?Yes. After Critical Compression (CrC) almost a fourth of the DM's resonance/ma ss has been ejected. And thus, the internal geometry is altered and its internal energy is no longer entirely reflected internally.

What happens to a Resoloid once it has been ejected in to the Dyosphere? Can it affect or penetrate another pulsoid?

What happens to a Resoloid once it has been ejected in to the Dyosphere? Can it affect or penetrate another pulsoid?Such a "free" Resoloid (www.Resoloid.com) is commonly referred to as light (incorrectedly as electromagnetic radiation). I've considered a separate neologism; however, I believe such would be counter-productive for connoting the relationship; thus, "unwinding," "free," etc.

When Resoloids (www.Resoloid.com) penetrate/collide with "Ma ss," there are equal, reactive reflections that reflect the energy of the "Ma ss"; thus, color, etc.

An interesting aspect is that a photon reflects in all direction with almost the intensity in every direction that was present prior to the reflection. Such is demonstrated by Feynman diagrams (www.CQthus.com/PT/FD) (FD).