A four-dimensional temporal hydrodynamic formulation unifies bioelectric morphogenesis and quantum coherent microtubular states through a conserved temporal transport field.
This paper presents a four-dimensional temporal hydrodynamic formulation in which bioelectric morphogenesis and quantum coherent microtubular states arise from a single conserved temporal transport field. The theory is constructed on a covariant spacetime manifold with a conserved chronoflux current, a norm-restoring regulator, and lowest-order couplings to biological voltage dynamics and quantum coherence sectors. The action, field equations, and invariant quantities are derived explicitly, producing chronoflux-dependent potentials, regulated stability conditions, and cross-scale invariants linking tissue-scale bioelectric networks to microtubular coherence domains. Quantitative predictions are obtained for repair kinetics, coherence times, and curvature-dependent shifts within a strictly four-dimensional formulation. The work forms part of the Chronoflux Research Initiative.
Roy Herbert (Tue,) reported a other. A four-dimensional temporal hydrodynamic formulation unifies bioelectric morphogenesis and quantum coherent microtubular states through a conserved temporal transport field.