Supplementary Simulation Note Simulation Summary A full forward-evolution run of a turbulent molecular cloud was performed using a dynamic-lattice, pregeometry-based field model. The simulation evolved the system for 10 million years, tracking emergent structure formation, topology transitions, and global-field behavior within a relativistic–field framework. Simulation Parameters Mode: Molecular Cloud EvolutionRegion: "Turbulent Molecular Cloud"Radius: 8 parsecsInitial Density Profile: Fractal turbulenceTemperature: 12 KBackground Magnetic Field: Weak fluxTurbulence Seed: 42 Physics Stack The dynamic-lattice model included: Relativistic gravitational response Magnetic-field interaction Quantum-emergent field behavior Vacuum-energy drift Curvature-response dynamics Pregeometry-based field-topology transition rules No classical n-body solvers, hydrodynamics, or Newtonian equations were used. Integration Details Time Direction: Forward Timespan: 10,000,000 years Step Size: 5 years Ensemble Size: 2048 lattice realizations Analysis Metrics The simulation continuously evaluated: Emergent structure formation Protostar-seed detection Density-clump tracking Field-line and topology coherence Output Overview Emergent Structures:11 coherent structure nodes formed between 0 AU and 10 AU, indicating early protostellar-like chain formation. Lattice Nodes: 55Topology Variance: 0.0 (perfect long-term coherence)Global Stability Metric: 6.285 Blueprint Encoding The final stable configuration consisted of 55 lattice sites.Each site includes: A symbolic state label (Φ, χ, H, Q, D) A position coordinate An 11-component internal state vector These symbolic states represent internal field-response categories: Φ: Flux-aligned χ: Curvature-sensitive H: High-stability Q: Emergent node D: Drift-dominated Predicted Field-Derived Properties Property Value Conductivity 3.9902 Structural Strength 4.39 Density 9.429 Thermal Stability 3.9956 Bio-Suitability Indicator 8.5351 These reflect emergent field behaviours of the final configuration and do not correspond to real physical materials. Synthesis Protocol (Derived from Blueprint) A theoretical synthesis pathway was generated from the final field state: Heating Temperature: 520 °C Cooling Rate: 14 °C/min Pressure: 8.54 atm Atmosphere: Nitrogen Duration: 88 minutes Note: Preserve alignment of field-interaction modes during transitional phases. Execution Notes The simulation exhibited pure emergent behavior without reliance on traditional physics solvers. The stable structure chain formed spontaneously from the dynamic-lattice evolution rules. No divergence, collapse, or topological fracture events occurred.

This study presents a 10-million-year forward-evolution simulation of a turbulent molecular cloud using a purely non-classical, pregeometry-driven field model. Instead of relying on gravity collapse, hydrodynamics, or n-body physics, the system evolves according to dynamic lattice rules governing field topology. Remarkably, the cloud spontaneously produced a coherent 0–10 AU chain of protostellar-like structure nodes with zero topology fracture and long-term geometric stability. These results suggest that early star formation may emerge from fundamental field-topology dynamics rather than classical mechanics alone.