Phenomenological Signatures of Heavy Topological Solitons in High-Energy Hadron Collisions

Current Beyond Standard Model (BSM) searches primarily rely on perturbative extensions to the electroweak sector to predict high-mass resonance states. This paper proposes an alternative framework utilizing non-perturbative solitonic states within a strongly coupled effective field. We predict the emergence of a heavy topological composite—a localized, multi-partite bound state governed by non-linear vacuum dynamics. When the internal energy density of this composite exceeds the confinement scale of the effective vacuum, the state undergoes rapid dissociation. Because these states possess extended topologies rather than existing as point-singularities, we propose their dissociation leaves a distinct kinematic footprint. This paper challenges the experimental community to re-analyze archived LHC Run 2 and Run 3 data for non-probabilistic, anisotropic decay distributions that strictly deviate from isotropic phase-space expectations.