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| Format: | Recurso digital |
| Sprache: | Englisch |
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2026
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| Online-Zugang: | https://doi.org/10.5281/zenodo.19326621 |
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| _version_ | 1866902148228317184 |
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| author | Slater, Matt |
| author_facet | Slater, Matt |
| contents | <p><strong>Update in Version 3:</strong> Includes new mathematical proofs defining the 'Lockstep Singularity' and the thermodynamic inevitability of human synthetic substitution.</p> <p>The <em>Slater Sphere Theorem</em> presents a unified conceptual and mathematical model for understanding how systems of any scale — social, biological, physical, or informational — form, sustain, and collapse through dynamic relationships of control, reward, and energy exchange.</p> <h3>Conceptual Overview</h3> <p>The theorem models systems as a series of nested spheres radiating outward from a core. Each sphere represents a degree of separation and maintains its own equilibrium of energy and autonomy. Control diminishes outward while accountability and environmental influence permeate inward. For stability, each sphere must generate or attract sufficient energy to sustain its structure without excessive extraction from the core or environment.</p> <p>Expansion requires proportional energy input and responsiveness to environmental feedback. Systems that overextend or fail to adapt lose coherence as entropy increases, eventually collapsing inward or fragmenting into new systems.</p> <p>The model unites organizational theory, systems science, thermodynamics, and evolutionary principles. It provides a predictive framework for stability, collapse, and adaptation, illustrating how sustainable systems balance control, reward, and environmental interaction.</p> <p>Originally derived from organizational dynamics, the theorem generalizes to all self-organizing systems and offers a universal map for understanding resilience, collapse, and the energetic logic of evolution.</p> <h3>Mathematical Framework</h3> <p>The formal edition of the theorem provides a quantitative structure for modeling energy distribution, entropy, and control gradients within multi-layered systems interacting with dynamic environments.</p> <p>Each sphere represents a degree of separation from the system’s core, defined by its energy state, control strength, and permeability. Control decays outward (∂C/∂r < 0), reward flows inward (∂R/∂r > 0), and systemic equilibrium is maintained when the net energy flux across spheres (ΣΔEi) remains positive.</p> <p>The theorem formalizes rules of expansion and contraction, introducing sustainability conditions such as dE/dt ≥ 0 and entropy minimization under environmental flux F_env. Systems that extract energy inward without replenishment experience entropy growth and collapse; those that generate or channel surplus energy adapt and evolve.</p> <p>Together, the conceptual and mathematical versions define a complete systemic geometry — a generalizable law describing stability, transformation, and adaptation across all scales of complexity.</p> |
| format | Recurso digital |
| id | zenodo_https___doi_org_10_5281_zenodo_19326621 |
| institution | Zenodo |
| language | eng |
| publishDate | 2026 |
| publisher | Zenodo |
| record_format | zenodo |
| spellingShingle | The Slater Sphere Theorem: A Complete Systemic Model of Energetic Stability and Environmental Interaction Slater, Matt Systems Theory Thermodynamics Thermodynamics Organizational Case Studies/organization & administration Organizational Innovation Applied mathematics Cybernetics Philosophy Philosophy Political sciences Business Business intelligence Structural biology Ethics Physics <p><strong>Update in Version 3:</strong> Includes new mathematical proofs defining the 'Lockstep Singularity' and the thermodynamic inevitability of human synthetic substitution.</p> <p>The <em>Slater Sphere Theorem</em> presents a unified conceptual and mathematical model for understanding how systems of any scale — social, biological, physical, or informational — form, sustain, and collapse through dynamic relationships of control, reward, and energy exchange.</p> <h3>Conceptual Overview</h3> <p>The theorem models systems as a series of nested spheres radiating outward from a core. Each sphere represents a degree of separation and maintains its own equilibrium of energy and autonomy. Control diminishes outward while accountability and environmental influence permeate inward. For stability, each sphere must generate or attract sufficient energy to sustain its structure without excessive extraction from the core or environment.</p> <p>Expansion requires proportional energy input and responsiveness to environmental feedback. Systems that overextend or fail to adapt lose coherence as entropy increases, eventually collapsing inward or fragmenting into new systems.</p> <p>The model unites organizational theory, systems science, thermodynamics, and evolutionary principles. It provides a predictive framework for stability, collapse, and adaptation, illustrating how sustainable systems balance control, reward, and environmental interaction.</p> <p>Originally derived from organizational dynamics, the theorem generalizes to all self-organizing systems and offers a universal map for understanding resilience, collapse, and the energetic logic of evolution.</p> <h3>Mathematical Framework</h3> <p>The formal edition of the theorem provides a quantitative structure for modeling energy distribution, entropy, and control gradients within multi-layered systems interacting with dynamic environments.</p> <p>Each sphere represents a degree of separation from the system’s core, defined by its energy state, control strength, and permeability. Control decays outward (∂C/∂r < 0), reward flows inward (∂R/∂r > 0), and systemic equilibrium is maintained when the net energy flux across spheres (ΣΔEi) remains positive.</p> <p>The theorem formalizes rules of expansion and contraction, introducing sustainability conditions such as dE/dt ≥ 0 and entropy minimization under environmental flux F_env. Systems that extract energy inward without replenishment experience entropy growth and collapse; those that generate or channel surplus energy adapt and evolve.</p> <p>Together, the conceptual and mathematical versions define a complete systemic geometry — a generalizable law describing stability, transformation, and adaptation across all scales of complexity.</p> |
| title | The Slater Sphere Theorem: A Complete Systemic Model of Energetic Stability and Environmental Interaction |
| topic | Systems Theory Thermodynamics Thermodynamics Organizational Case Studies/organization & administration Organizational Innovation Applied mathematics Cybernetics Philosophy Philosophy Political sciences Business Business intelligence Structural biology Ethics Physics |
| url | https://doi.org/10.5281/zenodo.19326621 |