Phase 4: Decay into the Quark-Broth and Genesis of the GRMHD Plasma
At the cessation of the inflationary epoch, the frozen potential energy must decay into thermalized matter.
- The Higgs Transition: The potential energy cascades directly into the Higgs field. Upon its decay, it generates an ultra-dense, relativistic broth of quarks, leptons, and gauge bosons.
- The Ignition of GRMHD: This primordial broth constitutes a perfect plasma with infinite electrical conductivity. The asymmetries and turbulences inherited from the ancestral dichotomous branching are converted—via the laws of General Relativistic Magnetohydrodynamics (GRMHD)—into ultra-intense hypercharge currents and primordial pre-magnetic fields. The resulting magnetic flux is rigidly "frozen" into the fluid substrate (flux freezing).
Phase 5: Implosive Mergers and the Stabilization of Time-Scales
The dynamical interaction between adjacent Monads within the phase space evolves across two sharply distinct temporal scales:
- The Primordial Implosive Era. In the immediate post-inflationary stages, the global density remains critical. Monads born in close proximity within the phase space undergo a frantic, near-instantaneous rate of collision and fusion (mergers). This violent hydrodynamical compression triggers the direct collapse of massive plasma domains into Primordial Black Holes (PBHs), which position themselves as foundational gravitational skeletons embedded within the plasma.
- The GRMHD Cosmic Time-Scale. As the metric expansion of the intervening space becomes dominant, the merger process experiences a significant deceleration. The Monads no longer fuse instantaneously or symmetrically; instead, they begin to negotiate their respective boundaries over vastly dilated periods (billions of years), shifting like tectonic plates across the terrain of the phase space.
Binomial Merging: Generating Black Holes and Clouds of Matter
The criteria of parsimony: Replacing "dark particles" with obscure matter from geometric statistics. Other effects shall be explained by other causes, eventually reducing the amount of estimated dark matter inside the universe.
- The Higgs Threshold: Baryonic scattering begins only after an energy threshold is crossed, allowing particles to acquire mass.
- Primordial Merging: Prior to this threshold, monads fuse according to a Binomial Distribution.
- Dark Matter Genesis: The high-density "tails" of this distribution collapse into Primordial Black Holes (PBHs) and Supermassive Primordial Black Holes (SMPBHs). Dark Matter is thus the result of "early merging" that bypassed the scattering phase, remaining gravitationally active but electromagnetically silent.
The effects to be searched and measured:
As the "Spray of Monads" dispels within the phase space, a massive process of re-aggregation begins. This is not a uniform condensation, but a Stochastic Merging governed by a binomial distribution.
- The Pre-Scattering Phase: Before the universe reaches the "Higgs Threshold," monads exist in a high-energy, massless state. During this era, they are free to merge without the internal pressure of baryonic scattering.
- Binomial Density Peaks: The merging process follows a Binomial Distribution. While the "main body" of this distribution forms the hot primordial soup, the "statistical tail" represents regions of extreme density.
- Primordial Black Hole (PBH) Genesis: In these high-density tails, monads collapse directly into PBHs and SMPBHs (Supermassive Primordial Black Holes). This happens before the creation of the first atoms, effectively "locking" a vast amount of the Mother-String's energy into gravitational wells.
- The Origin of CDM (Cold Dark Matter): Under this framework, Dark Matter is not an unknown particle but a population of primordial inclusions. These PBHs and "frozen" clouds of non-interacting dust provide the gravitational scaffolding for galaxies, explaining why Dark Matter is present even in the "peripheral" zones of our event horizon.
- The Higgs Filter: Only the monads that did not merge into PBHs survived to cross the Higgs Threshold. These "leftover" strings acquired mass and began the traditional scattering process, forming the baryonic (visible) matter we see today.