Understanding High-Energy Collisions in SDEF: Constraint-Driven Reconfiguration and Regime Transition

This work develops a conceptual interpretation of collider phenomena within the Scalar Drag Emergence Framework (SDEF) by treating high-energy interactions as processes of constraint injection. In this view, observed particle states are not fundamental entities but outcomes of constraint-driven reconfiguration following the disruption of stable corridor structures. The framework models post-collision dynamics as a reorganization of an underlying structural configuration governed by ancestry and constraint. The resulting observable states correspond to admissible attractor configurations of the projected GPLA dynamics under imposed constraints, rather than transformations of pre-existing particles. This perspective provides a unified structural interpretation of particle production, event topology, and anisotropic distributions in high-energy environments. It predicts that deviations from idealized behavior are not purely stochastic but exhibit geometry-dependent, structured patterns reflecting the underlying configuration dynamics. The work does not modify established collider predictions but offers an alternative interpretation that reframes particle production and correlation as emergent features of constraint-driven structural evolution.