5. Philosophical Shift: From Mass to Meaning
The Blink framework marks a philosophical transition:
From a universe built on mass-energy, to one emerging from resonant information.
The cosmos becomes a self-structured computation, not an explosion.
Geometry is not embedded, but emergent from interaction.
This echoes developments in quantum information cosmology, holographic principles, and even Wheeler's "It from Bit" vision.
The Blink Universe model, realized in analog systems, challenges the hegemony of the singularity-based Big Bang. Instead of postulating a mathematically extrapolated origin, it builds a physically reconstructible genesis from nonlinear information dynamics, coherence, and topological emergence---potentially transforming our understanding of both cosmology and the nature of physical law.
B. Entanglement, Information Causality, and Emergence
From Spin-Lattice Dynamics to Geometric Signatures
1. Bridging Scales: From Quantum Entanglement to Emergent Geometry
In conventional physics, geometry and topology are treated as background structures---spacetime is given, and matter moves within it. However, emerging theories across quantum gravity, condensed matter physics, and information theory suggest a reversal: that geometry is not fundamental but emergent, arising from microscopic information interactions.
In the Blink Universe model, this idea is explored through nonlinear excitations on a spin-lattice or magnonic substrate, where information is encoded, diffused, and entangled through localized and collective modes. The lattice acts not only as a medium for energy transfer but as a computational field, dynamically shaping metric-like behavior and curvature signatures from phase, amplitude, and resonance coherence.
2. Entanglement as a Driver of Locality
Quantum entanglement, rather than being a mere byproduct of quantum behavior, plays a constructive role:
