This paper extends the Temporal Torque Memory and Aether Organization series from numerical reconstruction methods to predictive physical cosmology. A temporal-torque density field, ₜ (x), is introduced as an emergent macroscopic order parameter describing organized five-dimensional chronogeometric memory within the Aether. Gradients of this field generate preferred transport pathways that naturally organize into filamentary corridors. Cosmic filaments are interpreted as integral curves of temporal-torque flow, while superclusters correspond to critical points of the temporal-torque landscape and cosmic voids emerge as minima of organized chronogeometric density. A variational principle is developed in which matter propagates through a combined temporal-torque and gravitational potential landscape according to xᵢ=-ᵢ ₜ-ᵢ G. Chronotorsional holonomy, represented by the scalar field ₜ, introduces intrinsic filament twisting and predicts persistent handedness statistics and large-scale helical organization. The theory predicts: filamentary residual cosmic birefringence corridors; statistical correlations between birefringence gradients and observed cosmic-web filaments; supercluster nodes corresponding to extrema of ₜ; cosmic voids as minima of organized temporal memory; anisotropic matter transport aligned with -ₜ; coherent gravitational torque amplification along temporal-torque corridors; persistent filament handedness and galaxy-spin correlations; correlations between filament handedness and residual birefringence signatures; preferred filament spacing scales characterized by c = 2 L (ₜ, ₜ) ; residual birefringence as a tracer of weakly luminous cosmic-web structure; multipole alignment signatures in future cosmic microwave background polarization surveys. The paper proposes that the observed cosmic web represents a fossilized manifestation of organized temporal-torque structure within the Aether. Gravity remains fully active as the dynamical amplifier and population mechanism, while chronogeometric organization establishes the preferred large-scale pathways along which coherent structure formation proceeds. This work constitutes Paper V of the Temporal Torque Memory and Aether Organization series: I. Temporal Torque Memory and Galactic-Scale Aether Organization: A Predictive Framework for Cosmic Birefringence. II. Aether Tomography: Residual Cosmic Birefringence as a Probe of Organized Five-Dimensional Chronogeometric Structure. III. Quantitative Definition of Temporal Torque Density and Chronotorsional Holonomy: A QMU Derivation of Organized Five-Dimensional Chronogeometric Structure. IV. Numerical Reconstruction of Organized Temporal-Torque Domains and Simulated Residual Cosmic Birefringence Maps. V. Filamentary Chronogeometry and Large-Scale Aether Organization: A Predictive Theory of Temporal-Torque Corridors and Cosmic Filament Structure.
David J. Thomson (Sun,) studied this question.