Boundary Vibrations as a Unifying Mechanism for Discrete Physical Phenomena

A wide range of physical phenomena—spanning nuclear stability, atomic spectroscopy, chemical reactivity, photon emission, and plasma behavior—exhibit abrupt transitions, discrete thresholds, and localized dissipation that resist smooth, bulk-based explanation. These features are typically treated as domain-specific anomalies rather than as manifestations of a shared underlying mechanism. This paper proposes that such phenomena arise from vibrations and reconfigurations of a microscopically localized coherence boundary, situated near the interface between internally coherent degrees of freedom and the surrounding laboratory environment. Treating this boundary as an effective physical interface, we introduce a phenomenological taxonomy of boundary-vibration modes and map them to long-measured but weakly unified observations across multiple fields. The framework emphasizes localization, threshold behavior, anisotropy, and metastability, and it yields concrete experimental discriminants that distinguish boundary-mediated dynamics from conventional bulk dissipation or intrinsic-property models. The analysis is deliberately independent of microscopic ontology, placing the existence and properties of boundary vibrations at direct experimental risk. If supported, boundary dynamics constitute a missing descriptive layer connecting stability and dissipation across scales; if not, the cataloged phenomena remain as a coherent set of constraints on any alternative explanation.