Quantum fluctuations may emerge as resonant excitations on modal backdrops.
The vacuum structure can be understood as mode-locked fields across quantized spacetime topologies.
This opens a pathway toward a quantum-resonant synthesis, potentially addressing long-standing questions about vacuum energy, decoherence, and the cosmological constant problem.
We propose the integration of this theory with quantum graphity, loop quantum gravity, or holographic resonance models as promising directions for unification.
8.3 Proposed Experimental and Observational Tests
To move this framework from speculative to testable science, we outline several concrete proposals for empirical validation:
1. Gravitational Wave Resonance Signatures
Hypothesis: If spacetime is a resonant medium, specific frequencies of gravitational waves should constructively interfere at cosmologically-preferred scales.
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Test: Cross-correlate LIGO/Virgo/KAGRA data with predicted resonance bands derived from modal equations.
2. Ultra-High Precision CMB Multipole Mapping
