1. The universe’s expansion accelerates due to gradients in information density, with dark energy arising from quantum entanglement entropy in holographic boundaries. 2. Gravity emerges as an entropic force from the statistical behavior of information in spacetime’s causal structure. 3. Dark matter corresponds to missing information entropy in galactic rotation curves, encoded in non-local quantum correlations. 4. The Higgs mechanism is a macroscopic manifestation of information constraints in quantum field theory’s causal diamond. 5. Quantum wavefunction collapse is a computational process resolving information redundancy in spacetime’s holographic projection. 6. The cosmic microwave background encodes primordial information entropy from the universe’s initial computational state. 7. Black hole entropy measures the information content of their event horizons, with Hawking radiation reflecting holographic data compression. 8. The Standard Model forces unify through information-theoretic symmetries in a Wheelerian “it from bit” framework. 9. Cosmic inflation resulted from information entropy maximization in a pre-geometric computational universe. 10. Gravitational waves represent information loss correction terms in the universe’s holographic description. 11. Dark energy is vacuum energy stabilized by cosmic-scale quantum coherence in an information-conserving universe. 12. Quantum entanglement correlations are quantized in spacetime’s information capacity per Planck area. 13. The Big Bang emerged from a computational phase transition in a higher-dimensional information manifold. 14. The universe is a hologram derived from information entropy on cosmic event horizons, projected via AdS/CFT duality. 15. Gravitons mediate information transfer between entangled spacetime regions in a causal set framework. 16. The speed of light bounds information transmission, with Planck-scale quantization determined by spacetime’s information density. 17. Dark matter interactions arise from non-local information sharing via topological defects in the cosmic information lattice. 18. CMB temperature fluctuations confirm inflation while encoding initial seed information for large-scale structure formation. 19. Quantum measurement branches split due to information decoherence in a von Neumann entropy landscape. 20. The universe’s expansion rate depends on information entropy gradients in dark matter’s quantum informational field. 21. Gravitational waves reflect information conservation laws in spacetime’s causal diamond geometry. 22. Baryogenesis occurred through information asymmetry in a parity-violating computational plasma. 23. The Higgs boson’s mass corresponds to an information entropy threshold in the Standard Model’s configuration space. 24. Planck-scale quantization arises from information entropy bounds in de Sitter spacetime’s holographic screen. 25. Quantum field excitations stabilize via information equilibrium in asymptotically safe gravity models. 26. Black hole entropy encodes cosmic information via holographic projections of large-scale structure connectivity. 27. Supersymmetric particles exist as information complements to ordinary matter in a dual computational universe. 28. The universe’s flat geometry results from information entropy minimization in the inflaton field’s computational landscape. 29. The Big Bang’s timeline includes gravitational wave signatures from information phase transitions in quark-gluon plasmas. 30. Dark energy density matches vacuum energy, stabilized by cosmic-scale quantum coherence in an information-conserving universe. ---