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

Fournier, Brenton

doi:10.5281/zenodo.18655671

preprintZenodo (CERN European Organization for Nuclear Research)Feb 16, 2026GREEN OA

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

BFBrenton Fournier

Indexed indatacite

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…

Citation impact

8

total citations

FWCI: —
Percentile: —
References: 5

Too recent for citation history.

Authors

1

BF
Brenton FournierCorresponding

Topics & keywords

Topics

Keywords

Observable
Entropy (arrow of time)
Scaling
Work (physics)
Convergence (economics)
Metric (unit)
Selection (genetic algorithm)
Component (thermodynamics)

UN Sustainable Development Goals

Affordable and clean energy

No related works found for this paper.