We generate and compare:
CMB temperature and E/B-mode polarization maps, seeking large-scale directional anomalies or axis alignments,
Hemispherical asymmetry indicators, measuring north-south and dipole modulations in CC_\ell,
Parrity-odd cross-correlations CTE,CTB,CEBC_{\ell}^{TE}, C_{\ell}^{TB}, C_{\ell}^{EB} expected to vanish under isotropy.
3. Simulation Results
Our simulations demonstrate that:
Constructive phase interference enhances the temperature fluctuation power at low multipoles <40\ell < 40, producing quadrupole-octopole alignment patterns similar to WMAP and Planck observations,
Destructive interference zones lead to localized cold spots (e.g., anomalies resembling the CMB Cold Spot),
Hemispherical power asymmetry emerges naturally when phase weights wn(x)w_n(x) vary slowly across large distances,
Polarization parity violations (e.g., non-zero CEBC_{\ell}^{EB}) appear in regions of high topological phase gradient.
These anomalies are not fine-tuned but arise statistically from phase correlation patterns seeded during the Blink Genesis and amplified by fractal self-structuring.
4. Predictive Observables and Constraints
From our interference simulations, we predict:
Correlated anomalies in CMB and LSS: the same phase patterns producing CMB anisotropies induce subtle modulations in galaxy number density and velocity fields, testable via LSST and Euclid,
Redshift-dependent polarization parity drift: CEB(z)C_{\ell}^{EB}(z) shows phase-dependent drift, allowing tomographic reconstruction of interference fields,
Phase knots and topological solitons: localized high-gradient regions act like topological defects, which could mimic effects of cosmic strings or textures in precision CMB surveys.
5. Comparison to Observational Data
The following observed anomalies find qualitative and quantitative correspondence with our simulation outputs:
CMB large-scale axis alignments ("Axis of Evil") --- reproduced via constructive interference near dominant phase regions,
Planck-reported hemispherical power asymmetry --- explained by coherent variation in wn(x)w_n(x),
Cold Spot depression --- reproduced statistically in 7%\sim 7\% of simulations without requiring exotic foregrounds.
Our numerical exploration of topological field interference across cosmological layers suggests that nonlocal phase entanglement in the early universe can coherently shape multiple observational anomalies. Unlike ad hoc inflationary corrections or dark energy tweaks, this approach unifies large-angle CMB anomalies, parity violations, and matter distribution asymmetries under a single geometrical and field-theoretic paradigm rooted in the Blink--Fractal--Layered cosmology.
V. Results and Observational Signatures
V.1. Explaining the Low Cosmological Constant Naturally
