Biological Time Equivalence in Vertebrates: Thermodynamic Framework, Comparative Tests, and Clade-Specific Deviations

Abstract

The product of resting heart rate and maximum lifespan is approximately constant across adult warm-blooded vertebrates, N = fH L ≈ 109 cardiac cycles, a regularity documented since Rubner (1908) but lacking a thermodynamic derivation. We derive N from the non-equilibrium second law by treating the adult organism as a metabolic non-equilibrium steady state (NESS) and introducing the closure ep = σ0 f, linking entropy production rate to heart rate via a mass-specific parameter σ0 M0. Integration yields a finite dissipative budget = σ0 N, identifying N = /σ0 as the correct primitive conserved quantity; lifetime energy per unit mass is a derived consequence valid only under simultaneous constancy of body temperature and σ0. Phylogenetically independent contrasts on 112 endotherm species yield a fH-- L slope of -0.99 0.04 (p=0.84 against -1); the West--Brown--Enquist null of zero inter-clade variation is rejected (F=12.7, p<0.001). A factored multiplier C = duty · thermal · mito · haz, calibrated from independently measured physiology, accounts for longevity deviations across four warm-blooded clades. The integral of physiological frequency defines a biological proper time classifying longevity mechanisms as time dilation (reduce f) or budget expansion (reduce σ0). The decisive test is calorimetric measurement of σ0 = P/(TfM) across three body-mass decades.

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