Volume XXV investigates the deep structural organization of the tension-field that underlies the entire R-layer Mode Theory (RLMT). Building on the static, dynamical, cosmological, and quantum–gravitational analyses developed in Volumes XXI–XXIV, this volume reveals the internal architecture that makes the R-layer hierarchy possible. The tension-field is shown to possess a layered microstructure composed of nested informational gradients, self-stabilizing modes, and cross-scale coupling channels. These structures determine how information propagates across layers, how coherent modes form, and how stability is maintained throughout the hierarchy. The central results include: Deep informational gradients: Fine-scale gradients support quantum fluctuations, intermediate gradients regulate classical coherence, and large-scale gradients shape gravitational curvature and cosmological evolution. Self-stabilizing modes: Structural anchors embedded within the tension-field maintain coherence across scales, giving rise to quantum stability, classical trajectories, and global curvature patterns. Cross-scale coupling channels: Information flows bidirectionally across layers, allowing quantum fluctuations to influence macroscopic behavior and global gradients to constrain microscopic dynamics. Generation of the R-layer hierarchy: The interplay between gradients, stabilization, and coupling dynamically generates the multi-layered structure of physical regimes—quantum, classical, gravitational, and cosmological. Foundational architecture: The unity of physical law arises from the unity of informational architecture within the tension-field. Volume XXV provides the structural foundation of RLMT and prepares the ground for subsequent volumes, where the mathematical formulation of the tension-field and the dynamics of R-waves will be developed.
Tsuyoshi Tohi (Fri,) studied this question.