DEBA - A Complete Cosmology Without Postulates, Answers to Anomalies

DEBA (Determinists Emergence By Actualization - Organizational Coherence Cosmology) is a cosmological framework based on stochastic field theory in pre-metric configuration space. Proposed by Michel Debailleul (2025), the framework explains multiple cosmological anomalies observed by Planck and JWST through a unified mathematical formalism without requiring ad hoc hypotheses.

Unlike the ΛCDM model, DEBA posits that universe-bubbles emerge via organizational coherence condensation from an atemporal, non-metric primordial void. Physical laws, constants, and spacetime itself emerge locally within each bubble rather than being universal.

Advantages Over ΛCDM

Conceptual Coherence

•             No initial singularity: Primordial void is atemporal; temporal singularity is observational artifact

•             No fine-tuning: Constants emerge from stochastic condensation, not imposed

•             Finite structure: All physical quantities bounded; no infinities

•             Local physics: Laws and constants are bubble-specific, not universal

Explanatory Power

•             Unified framework: Single organizational coherence dynamics explains multiple anomalies

•             Natural predictions: CMB anomalies, early structures emerge without new parameters

•             Quantitative: Provides calculable predictions, not qualitative hand-waving

•             Testable: Multiple falsifiable predictions for near-term observations

Mathematical Rigor

•             Derived from established stochastic field theory

•             Uses large deviation theory (Freidlin-Wentzell) for trajectory probabilities

•             Functional Langevin dynamics provides well-defined master equation

•             Stopping time formalism rigorously defines emergence event

Numerical Simulation

DEBA is computationally simulable via:

1.          Stochastic sampling of coherence distributions on discretized C

2.          Percolation models at threshold μ_min

3.          Monte Carlo methods implementing Eq. (1) master equation

4.          Correlation propagation in emergent spacetime

5.          Multi-observable joint confrontation with data

Preliminary simulations reproduce: - Bubble emergence and flash nucleation - Fragmentation into disjoint domains - Coherence gradient structures - Statistical properties matching observations