The Underlying Dynamics of Life and Its Evolution: A Prigogine-Inspired Informational Dissipative System

Life is fundamentally a scientific enigma. The interplay between chaos, entropy dynamics, and Prigogine's dissipative systems offers profound insights into the emergence, stabilization, and eventual collapse of far-from-equilibrium systems. This study proposes that, alongside thermodynamic dissipative systems as highlighted by Ilya Prigogine, informational dissipative systems actively contribute to granting inanimate matter properties characteristic of living systems, such as autopoiesis. By examining cyclic entropy flows between water topology (Shannon space) and molecular systems (Boltzmann space), the work emphasizes the pivotal role of disquisotropic entropy, an informational entropy reservoir arising from imperfections in molecular structures. The analysis demonstrates that chaos functions as a stabilizing force, enhancing resilience, adaptability, and longevity by delaying thermodynamic equilibrium. This research connects foundational thermodynamic principles with the emergent behavior of chaotic systems, paving the way for a deeper understanding of complexity in natural and technological contexts. By exploring the relationship between chaos, entropy, and dissipative dynamics, the study advances a paradigm where disorder becomes a mechanism to sustain order, a hallmark of life and complex systems.