What does this research mean for the field?

High-dissipation configurations of technological systems become structurally fragile over gigayear timescales due to superlinear scaling of maintenance burden with energetic throughput. Novelty: ClaimNovelty.NOVEL_FINDING. Consensus alignment: ConsensusAlignment.NEUTRAL.

What question did this study set out to answer?

This research aims to reframe the evaluation of technological persistence by focusing on thermodynamic constraints.

February 19, 2026Open Access

Thermodynamic Convergence in Deep Time: A Constraint-First Reframing of Persistent Technological Systems

Key Points

This research aims to reframe the evaluation of technological persistence by focusing on thermodynamic constraints.
Developed a constraint-first framework
Analyzed energy flux and entropy production
Examined maintenance burdens and structural fragility
Investigated the relationship between energetic throughput and component degradation
Identified conditions leading to superlinear maintenance scaling
Found that high-dissipation configurations are structurally fragile over long timescales
Demonstrated that increased sensitivity in energy metrics does not enhance performance after deep-time filtering

Abstract

This paper develops a constraint-first framework for evaluating the long-term persistence of technological systems under thermodynamic limits. Beginning from finite energy flux, irreversible entropy production, component degradation, finite signal speed, and duration-weighted survival, it derives conditions under which maintenance burden scales superlinearly with energetic throughput. If maintenance scaling is superlinear, high-dissipation configurations become structurally fragile over gigayear timescales. Repeated selection suppresses variance in bulk energy-integrated observables while leaving orthogonal structural dimensions comparatively unconstrained. Increased sensitivity in a single energetic metric therefore does not guarantee improved separability after deep-time filtering. This work forms the thermodynamic layer of the Deep-Time Structural Constraints series.

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