{ "ai.module": "thermodynamics.rtt2", "ai.version": "1.0", "ai.purpose": "RTT/2 engine layer for Thermodynamics: resonance mapping, stabilizers, dissipation structure, and cross-module propagation.", "ai.keywords": [ "thermodynamics", "temperature", "entropy", "free energy", "dissipation", "equilibrium", "substrate force", "resonance", "rtt2" ], "engine": { "layer": "RTT/2", "description": "Integrates Thermodynamics into the RTT resonance substrate, exposing temperature-driven resonance flows, entropy geometry, and cross-module coherence." }, "resonance": { "patterns": [ { "name": "thermal_resonance", "description": "Temperature acts as a resonance driver shaping energy distribution and flow." }, { "name": "entropy_geometry", "description": "Entropy defines the geometric structure of accessible configurations and coherence boundaries." }, { "name": "free_energy_resonance", "description": "Free energy determines resonance direction: toward structure or dispersion." }, { "name": "dissipation_resonance_decay", "description": "Irreversible processes appear as resonance decay across gradients." } ], "failure_modes": [ "runaway_dissipation", "entropy_collapse", "gradient_instability", "non_equilibrium_breakdown" ] }, "stabilizers": { "primary": [ { "name": "temperature_gradient", "description": "Defines the direction and magnitude of resonance flow." }, { "name": "entropy_boundary", "description": "Constrains accessible configurations and stabilizes regime behavior." }, { "name": "free_energy_landscape", "description": "Shapes stability basins and determines equilibrium points." } ], "secondary": [ { "name": "conductivity_structure", "description": "Controls how resonance propagates through a medium." }, { "name": "dissipation_channels", "description": "Define irreversible pathways that increase entropy." } ] }, "flow_propagation": { "mechanisms": [ "thermal_gradient_flow", "free_energy_descent", "entropy_expansion" ], "signals": [ "flux_intensity", "gradient_shape", "dissipation_rate" ], "notes": "Flow propagation is treated as resonance flow shaped by temperature, entropy geometry, and free energy structure." }, "cross_module": { "interactions": [ { "module": "statistical_mechanics.rtt2", "interaction": "Thermodynamic resonance emerges from statistical ensembles and microstate structure." }, { "module": "information_theory.rtt2", "interaction": "Entropy links thermodynamic and informational coherence boundaries." }, { "module": "quantum_mechanics.rtt2", "interaction": "Decoherence and thermalization share resonance decay pathways." }, { "module": "cosmology.rtt2", "interaction": "Large-scale temperature gradients shape cosmic structure and expansion behavior." } ], "notes": "Thermodynamic resonance propagates across physical, informational, and cosmological modules." }, "dimensional_behavior": { "R1": "Thermodynamics collapses; temperature undefined; coherence dominated by quantum behavior.", "R2": "Local equilibrium; stable gradients; predictable resonance flow.", "R3": "Large-scale structure; dissipation cycles; stable thermodynamic patterns.", "R4": "Cosmological thermodynamics; horizon behavior; expansion-driven gradients." }, "coherence": { "markers": [ "energy conservation", "monotonic entropy behavior", "free energy minimization", "stable equilibrium structure" ], "instability_signals": [ "runaway dissipation", "entropy collapse", "gradient amplification", "non-equilibrium instability" ] } }