This article proposes a formal unification between Evolutionary Game Theory, non-equilibrium irreversible thermodynamics, and the Theory of Finite Systems framework. We postulate that biological instinct (reproductive/sexual) acts not merely as a behavioral preference variable, but as a non-conservative systemic pressure gradient (∇Φinst) that perturbs the stable attractors of the rational payoff matrix. We analytically demonstrate that a strict, unperturbable Nash Equilibrium induces a structural "heat death" (dx/dt = 0), collapsing the system's capacity to generate useful work or adaptive evolution. To resolve this paralysis, the instinctive vector injects internal entropy (diS > 0), allowing the system to execute phase transitions analogous to the simulated annealing algorithm. This dynamic is strictly regulated by the Ramanujan-Hernández Packing Factor (ΦRH ≈ π) and the Hernández-Valdivia Limit (εHV ≈ 10-70 m2) through an adaptive hyperviscosity operator based on the Frobenius norm. This mathematical coupling guarantees that the energy injection dissipates the stochastic excess before fracturing the phase space, consolidating the nature of populational systems as self-regulating finite-state machines.
Carlos Mariano Hernández Valdivia (Sun,) studied this question.