A Theory of a Higher-Order Informational Layer in Physics: The Universal Structural Code as the Formal Core of the PJM Programme

Description / Introduction This repository contains two complementary documents that together form the foundation and formal core of the research programme of the Law of One Mechanism (PJM) and the GTWSSF–USC–GTCW framework within the broader PJM research architecture. The material presented here proposes a deep deconstruction of the scalar paradigm in contemporary physics. This does not mean rejecting the established achievements of the Standard Model, general relativity, or quantum field theory. Instead, it introduces above them a higher-order relational and selective layer referred to as the Universal Structural Code (USC). In this formulation, the central question becomes why, out of the enormous number of mathematically admissible configurations of nature, only some are physically realized, while others remain unstable, decay immediately, or never attain the level of stable physical manifestation. The repository consists of two integral yet publication-independent parts. 1. Main Article (Document BK-Y09) This document establishes the definitional and formal skeleton of the theory. Its principal achievements include: A redefinition of the notion of information in physics. The USC code is not treated as a digital, binary, or algorithmic record. It is defined instead as a continuous, generative, and relational set of rules of consistency and selection for configurations of dynamic couplings. A new ontology of physical structures. The document rigorously distinguishes between: code as the set of admissibility rules, pattern as the observable manifestation of the action of the code in the space of observables, physical structure as the stable and stationary realization of a pattern. An apparatus of stability and instability. A formalism is introduced that includes a vector of dynamical parameters, a set of consistent configurations, and a measure of code inconsistency DzDzDz, making it possible to interpret instability not only as a consequence of excess energy, but also as a result of the structural distance of a configuration from the rules of the code. 2. Technical Annex (Document BK-Y10, Sections A1–A18) The annex constitutes the hard analytical backbone of the programme, in which the definitional apparatus of USC is developed into explicit mathematical and physical constructions, working models, and quantitatively testable predictions. It includes, among other elements: Experimental CERN anchors (A1–A3). The USC logic is applied to CMS and ATLAS results in the threshold regime of ttˉttttˉ production, indicating that the proper choice of angular and threshold observables may reveal the hidden structure of quasi-bound states. Sector-specific developments (A5–A13). These include the implementation of USC for the Higgs sector, relativistic developments based on the Dirac equation and the chiral anomaly associated with the γ5⁵γ5 matrix, as well as extensions to the neutrino sector, including see-saw type mechanisms with code-based corrections. Falsifiable predictions (A9, A14–A17). The annex provides reference MasterData tables and PASS/FAIL criteria for upcoming experiments such as HL-LHC, DUNE, and Hyper-Kamiokande, together with quantitative forecasts concerning, among other topics, CP violation, sterile neutrinos, and neutrinoless double beta decay 0νββ00νββ. Connection with holography (A18). The USC layer is discussed as a selective boundary structure compatible with holographic duality of the AdS/CFT type. Significance of the Publication The materials collected in this repository are intended for theoretical physicists, researchers in high-energy physics, neutrino physics, cosmology, and philosophy of science. They propose a new descriptive language in physics in which the relational and structural layer does not replace known dynamics, but organizes the space of admissible physical realizations. In this sense, the publication opens a path toward a fully calculable structural and informational layer designed for further calibration and empirical testing in next-generation experimental programmes. Keywords PJM (Law of One Mechanism), GTWSSF, Universal Structural Code (USC), metafield mechanics, modal selection, high-energy physics, threshold phenomena, neutrino oscillations, Higgs boson, philosophy of physics, DUNE, Hyper-Kamiokande, HL-LHC