The quantum blink genesis ensures causal connectivity via a tunneling instanton that spans the entire emergent spacetime hypersurface (see Sec. II.1),
Layered topological entanglement maintains long-range phase coherence across proto-structures,
The fractal geometry embeds pre-inflation-like scale invariance intrinsically in its initial conditions.
This eliminates the need for a separate inflationary phase, avoiding associated fine-tuning issues (e.g., inflaton potential flatness, reheating efficiency, monopole dilution).
The proposed cosmological framework explains three key observational puzzles that strain CDM:
Early formation of massive galaxies at z>10z > 10,
Anisotropic voids and directional structures in the large-scale matter distribution,
Coherent spin alignments of galaxies and satellite systems.
All of these arise as natural consequences of a fractal-topological genesis---without recourse to inflation, fine-tuned perturbations, or dark sector anomalies. This predictive success suggests that our framework offers a viable, unifying direction for post-CDM cosmology.
V.3. Signatures Accessible to JWST, Euclid, and SKA
The integrated framework presented---encompassing Quantum Blink Genesis, Multilayer Topological Architecture, and Fractal Matter Geometry---yields several distinct, testable predictions that diverge from standard CDM expectations. These predictions produce specific signatures that are accessible to ongoing and forthcoming high-precision surveys, particularly the James Webb Space Telescope (JWST), Euclid, and the Square Kilometre Array (SKA). Below, we summarize key observable features and the instruments best suited to detect them.
1. High-Redshift Mature Galaxy Abundance
Instruments: JWST, Euclid
Our model predicts an enhanced population of massive, metal-enriched galaxies at redshifts z>10z > 10 due to the scale-invariant, fractal seeding mechanism and early local overdensities arising from topological layer overlap.
Observable via:
Infrared photometry and spectroscopy (JWST NIRCam, NIRSpec),
Photometric redshift distributions (Euclid's deep-wide optical/IR survey).
Expected deviation: Number densities of galaxies at z>10z > 10 exceeding CDM expectations by orders of magnitude, with anomalously high stellar masses and rapid star formation rates.
2. Anisotropic Voids and Hubble Flow Variations
Instruments: Euclid, SKA
The multilayer topological model allows for radial and directional variations in Hubble expansion, with anisotropic voids acting as dynamical boundaries.
Observable via:
Tomographic galaxy clustering and BAO mapping (Euclid),
Neutral hydrogen intensity mapping via 21cm line surveys (SKA-MID, SKA-LOW).
Expected deviation:
Detectable dipole or quadrupole modulations in local Hubble flow beyond cosmic variance,
Spatially correlated void ellipticity and galaxy distribution distortions that deviate from isotropic simulations.
3. Coherent Galactic Spin Alignments
Instruments: SKA, Euclid
