Molecular and Cellular Biology Foundations: The Topological Container and Informational Molecules of Life. Volume I of the Axiomatization of Biology in the Global-Realism Framework

This manuscript initiates the biology program within the global-realist framework by deriving the first biological layer from the already closed physical and chemical programs. Its task is not to introduce “life,” “cell,” “gene,” “enzyme,” or “metabolism” as primitive explanatory terms, but to show how they emerge as lawful structures built from the state-description, transport, self-assembly, recognition, and inverse-reading layers already established in the six physical manuscripts and the six chemistry volumes. We define the admissible input interface for biology, prove that biology is a conservative extension of chemistry rather than a new ontology, and formulate life as an open far-from-equilibrium carbon-based topological reactor endowed with a protected boundary, a chemically realized information-bearing polymer sector, and a catalytically controlled reaction network. We then derive the physical necessity of the cellular membrane as a closed amphiphilic bilayer selected by hydrophobic free-energy reduction, packing geometry, and edge-elimination energetics. A critical closure criterion is obtained by comparing the edge energy of an open bilayer patch with the bending energy of a closed vesicle, yielding the threshold area above which closure into a topological container is favored. The result is the first volume of a biology axiomatization: it closes the logical passage from chemistry to minimal cellular organization and establishes the topological and informational prerequisites for later treatments of metabolism, genetic replication, regulatory feedback, and evolution.