This work presents a structural interpretation of the electron in which its fundamental properties—charge, spin, and interaction—are derived from coherence structure rather than introduced as intrinsic postulates. The electron is described as a stable resonance configuration within a coherence-based field framework, allowing a unified physical interpretation of electromagnetic interaction, electron correlation, and atomic structure. A key aspect of the model is that the electron is not fully confined to three-dimensional space, but extends along an internal coherence dimension. Observable behavior is interpreted as a projection of this deeper structure, providing a structural basis for delocalization, tunneling, and orbital formation. Within this framework, charge arises from asymmetry in lateral coherence, while spin is understood as an internal phase-topological property. Electron–electron interaction is described in terms of coherence interference, offering a structural explanation for repulsion, pairing, and exclusion behavior. Electromagnetic phenomena are interpreted as coherence dynamics: fields correspond to continuous structure, while photons are treated as localized propagating excitations. This provides a unified but differentiated description of electromagnetic interaction. The framework is consistent with established theoretical descriptions while providing a physically interpretable basis for electron structure and its role in electromagnetism and atomic systems. It aims to clarify conceptual foundations rather than replace existing predictive models, and establishes a basis for further work in atomic structure and chemical behavior.
Henrik Nilsson (Sun,) studied this question.