I. The Primordial Phase: From Probability to Monads
Time | Era | Phenomena | Boundary annotations |
0 to 5,391*10E-44 s | Pre-Planck | Probability Deployment: The Mother-String unfolding. Primordial String deploys its density of probability | Undefinite time and space, just deployment of the probabilities, of 1, 2, 4 ... sub-strings. At T(Planck) space-time emerges from the a 10D probability density. |
5,391*10E-44 s to 10E-26 s | Recursive Fractionation: Strings multiply into independent monads | Superluminal phase-time, with causal isolation of sub-strings-monads. Strings start to have phase time and space, but it is superluminal and each sub-string is not affected by others as their gravitational time and space is out of the monad-horizon | |
10E-26 s to 10E-24 s | Higgs-String Interaction | High density scattering and merge of monads. Inelastic scattering reduces relative velocities. | particles soon find other particles, sometimes they interact merging into a string that decade at once, sometimes they scatter elastically |
10E-24 s to 10E-12 s | Normalization and Crystallization | Lower density scattering and merge inside monadic-pre-universes. At the end, the pre-universes become entities that might be mapped into CMD models. | Dynamics: Internal scattering decreases drastically. Within the Sweet Point, the evaporation-tear slows down, allowing mass condensation. Result: Inside the monad-pre-universe, the first stable PBHs (and SMPBHs) are formed. What remains outside the singularity becomes Dense Dust. There us a region in the phase space where pre-universes have a proper ratio in PBH vs matter is established; mass distribution of monads is binomial. |
II. The Structural Seeding: 10E-12 s to 200 My
Time | Era | Phenomena | Boundary annotations |
10E-12 s to seconds | Cooling and Autonomy | Thermodynamics of the Higgs Field: Each pre-universe is an "Island" with its H-soup that continues to cool adiabatically, forming barionic dust and centers of gravitational attraction for future clouds and pbh | Differentiation: Depending on the radial shell (Phase Center vs. Periphery), the monad completes its internal evolution at different rates. Internal monads become "Dark" (almost entirely PBH), while outer ones remain "Dusty" (H-clouds). CMD: End of the unfolding phase; the simulator begins mapping pre-universes as entities with defined Mass, Angular Momentum, and Radius. |
up to 50 M Y | Structural seeds | Mergers reshuffle histories. Dusty monads fuse with Dark monads. | Secondary Genesis: Baryonic dust within the pre-universes start collapsing into future stars and second generation of black holes (BHs). |
| 100 M Y | Pre-Inclusion Era | Origine di Shapley | phase inducted formation |
| 150 M Y | Shapley includes Laniakea | merge of phase inducted formations | |
| 50 to 200 Mil Y | Dust accretion within the Local Cluster | Our primordial cloud exists as a satellite accretion within the 'gravitational wake' of the Great Dust (Laniakea). At this stage, we are not yet galaxies, but a plasma domain inheriting the angular momentum (spin) from Laniakea’s macroscopic rotation. |
III. The Inclusion Era: 200 My to 2 Gy
Time | Era | Phenomena | Boundary annotations |
| 200 M Y | Inclusion Era | Annexation into the Laniakea-Shapley Complex | Primordial plasma inherits Laniakea's macroscopic spin and the local plasma domain is formally integrated into the macroscopic kinematic flow. The gravitational wake of the "Great Dust" (Laniakea) synchronizes with the Shapley attractor, establishing the first large-scale Phase-Resonance. This event dictates the long-term inertial drift of our sector within the Equatorial Web. |
| 200-320 ML | early galaxies | PBH intrusions explain the "Impossible Early Galaxies" observed by JWST (z>14). These structures did not evolve through slow accretion but were too fast. | |
| 290-320 M Y | SMPBH Intrusion into the Local Cluster: Origins of the Oldest Observed Galaxies | Our primordial cloud exists as a satellite accretion within the 'gravitational wake' of the Great Dust (Laniakea). The intrusion of a Super-Massive Primordial Black Hole (SMPBH) into our local cluster. This ballistic event triggered the rapid collapse of the primordial plasma, forging the oldest observed galaxies through a process of kinematic 'pinching' rather than slow accretion. The captur amidst the turbulence generated by the SMPBH's transit justifies the simmetries around the axis of the filamento toward Laniakea. | |
| 320-600 M Y | Filamentation toward Lamiakea | The SMPBH continues its ballistic trajectory toward the heart of Laniakea (the Great Attractor), dragging and accreting matter within its wake. | Ballistic SMPBHs "stretch" the local mesh (Filamentation). Note: An empirical age gradient of stellar formations is observed along the filament. The two masses are likely already in resonance, triggered by the merging wave with Shapley. |
| early galaxies | SMPBH Intrusions continue | Early Galaxies (JWST) form as "Collars". | |
| 600-800 M y | Ancient Galaxies in Hercules | Red and dead galaxies depleted their gas reservoirs billions of years ago, ceasing new star formation. | Within the Kinematic model, they represent the primary 'Collars' stabilized around primordial inclusions. |
| 800My-1,5Gy | Consolidation of the Sloan Great Wall | Asynchronous Accretion of Sloan and Boss Great Walls. | phase inducted formation Ancient "red and dead" kernels act as gravitational anchors. |
| 1-2 Gy | Consolidation of the Boss Great Wall |
IV. The Great Coupling: 2 Gy to Present
Time | Era | Phenomena | Boundary annotations |
| 2-4 Gy 3-5 Gy | Rarefaction of Major Merger Events | Emergence of the Filamentary Weft | Major merger events decrease. The universe transitions from apocalyptic chaos to a coherent, synchronized network. |
| 4-10 Gy | Cosmic Web Connection | The universe transitions from an 'apocalyptic' era of violent mergers to a stable, synchronized regime. | Transition to Topographic Inertia: Acceleration emerges as relaxation. Direct observational evidence begins to emerge, moving beyond purely 'fossil' data. |
| 6-8 Gy | The Great coupling | The Milky Way's Thin Disk shows a major resurgence in star formation
and a transition to orbital quiescence exactly 7 to 8 billion years ago. This timing coincides with the cessation of major destructive mergers and the onset of an ordered "flow" toward a larger structure—marking our formal annexation into a network among the pre-existing lines of the Equatorial Web. | 1. Formation of the Milky Way’s Thin Disk The Laniakea-Shapley axis is not a mere gravitational attraction; this Topological Link marks a formal capture. 2. The Topographic Inertia Transition The observed acceleration of the universe becomes dominant around T = 7.0 Gy. This is the pivotal moment when the cosmic mesh ceases to be dominated by local stochastic impacts (mergers) and begins to stretch as a single, coherent fabric. The annexation of our local periphery is a fundamental component of this final "tightening" of the global network. 3. The Dynamic Watershed (Nested Basins) When the Laniakea Supercluster was first mapped by R. Brent Tully and his team, it was defined by its internal "basins of attraction," where galaxies drift inward toward a local gravitational center known as the Great Attractor. 4. Coherent Vectorial Alignment Cosmographic velocity maps (such as Cosmicflows-4) confirm that Laniakea is not a static, isolated bubble. While galaxies inside Laniakea flow internally toward the Great Attractor, the entire 500-million-light-year supercluster possesses a highly synchronized, net peculiar velocity of 600 to 1,000 km/s structurally oriented instead toward the massive Shapley Supercluster. |
| 10 Gy - today | Toward Equilibrium | Slower Cosmic accretion | Rare intrusions; weakening of GRB and neutrino flux and the mesh tension equilibrates. |