The Resolution: The 5 hidden domains do not cluster identically to the Prime domain because their distinct orbital velocities on the 5D Kaluza-Klein cylinder alter their proper time. Conformal gravity time-averages these 5 offset orbital shells. When summed with our central Prime halo, the resultant aggregate density profile mathematically flattens into an isothermal sphere: ρ_Tav(r) ≈ v₀² / (4π G r²).
The Resolution: Light in the Prime domain travels across the 4D bulk but is anchored to the underlying 5D Twistor space via Planck-Kerr (PK) mirrors. The massive, offset hidden domains warp this 5D substrate. Because PK mirrors act as a "superlubricated" interface (zero EM absorption), the photon's path is efficiently guided and bent by the sheer geometric Weyl curvature.
The Resolution: During galaxy cluster collisions, the visible gas experiences extreme electromagnetic ram pressure and halts. The 5 hidden domains (χ-fields) interact only via conformal gravity. They pass straight through the plasma crash unimpeded, carrying the majority of the gravitational lensing peaks along with them.
The Resolution: Standard hot dark matter would wash out early galaxy formation. In Tav-Superblock, the 5 hidden domains are entirely macroscopic spacetime sheets. Their time-averaged gravitational shadow is fundamentally static and "cold" relative to our expanding Prime domain, acting as stable gravitational wells to seed early structure.
The Resolution: The 8-phase discrete torsion of the octonionic fiber strictly enforces topological exclusion. EM radiation requires a shared phase to couple. The 5 hidden domains sit at orthogonal ticks of the universal clock. They are electromagnetically out-of-phase.
The Resolution: The 3 "past-oriented" domains are the CPT-conjugates (antimatter) of the 3 "future-oriented" domains. They do not instantly annihilate with our universe because they are topologically segregated by the 8-phase cycle.
The Resolution: The fields are constrained by the 313.1 MeV Conformal Mother mass gap. Their exact mass contributions are locked by their Lorentz factors derived from their orbital velocities.
Prove that summing the mass density of 1 visible domain and 5 phase-shifted hidden domains perfectly reproduces the 1/r² density profile required for flat galactic rotation curves.