Thermodynamic Parametrisation of the Vertebrate Lifetime Cycle Invariant: Biological Proper Time, Allometric Mass-Cancellation, and Clade-Specific Predictions

Abstract

Warm-blooded vertebrates accumulate approximately ≈ 109 cardiac cycles over a natural lifetime, a striking empirical regularity first quantified by Lindstedt and Calder yet lacking a physical interpretation. We propose that this invariance is consistent with a conserved thermodynamic budget, formulated here as the Principle of Biological Time Equivalence (PBTE). The framework rests on a constitutive closure = σ0 f, which links the entropy production rate to the intrinsic physiological frequency; integration over the lifespan yields life = σ0 , so that the observed constancy of corresponds to an approximately constant lifetime entropy budget. Algebraic exponent cancellation under Kleiber and Calder scaling laws, M3/4+1/4-1=M0, is consistent with mass-independence and reproduces the numerical value N0 ≈ 1.52×109 without free parameters. The framework offers a thermodynamically consistent account of two outstanding problems: the origin of the numerical value of and the systematic deviations observed across clades. A multiplicative correction factor C, constructed from physiological determinants -- activity allocation, body temperature, mitochondrial efficiency, and extrinsic hazard -- predicts long-lived clades as regimes of reduced effective entropy production per cardiac cycle.