Title: The Chrono-Genetic Universe: A Unified Field Theory of Mass-Time Indexing, Stellar Parturition, and Planetary Evolution Abstract: The standard Lambda-CDM cosmological model currently faces a crisis of convergence, characterized most acutely by the 5-sigma tension between early- and late-universe measurements of the Hubble Constant (H0) and the persistent failure to detect WIMP Dark Matter candidates. Simultaneously, planetary formation theory is challenged by the ubiquity of "Hot Jupiters" and the biomechanical paradox of Mesozoic gigantism under a 1g field. This paper proposes the "Chrono-Genetic Universe" model, a unified theoretical framework that abandons the static background assumption of General Relativity. We introduce the Mass-Time Index (MTI), a scalar field that couples local temporal density to mass-energy flux. By treating the galaxy as a reproductive fluid vortex rather than a collisionless N-body system, we demonstrate that: Galactic Dynamics: Super-Keplerian rim velocities are sustained by Fluid-Lorentz forces acting within a "Thinner" spacetime index, eliminating the need for Dark Matter. Stellar Reproduction: Main-sequence stars undergo secular instability and fission ("Stellar Parturition") to eject planetary cores, providing a natural explanation for the distribution of exoplanets without migration. Planetary Evolution: Planets evolve via endogenic mass generation, driving a punctuated surge of radial expansion that resolves the Mesozoic gravity anomaly. We present a definitive Falsification Suite, including the "Washburn" Signal - a transient-transit correlation protocol - and isotopic forensics of halo stars to test this hypothesis. Keywords: Dark Matter, Hubble Tension, Mass-Time Index, Stellar Fission, Planetary Expansion, Magnetohydrodynamics, Cosmology, Geophysics, Exoplanets Creators: Hallelujah, Paul (University of Toronto/Queen's University Alumnus) Publication Date: February 2, 2026 Language: English Resource Type: Preprint Subjects: Astrophysics; Geophysics; Cosmology; Theoretical Physics