Coherence Interference and Local Field Amplification in Electromagnetic Systems. A Coherence-Based Interpretation of Polarization and Energy Concentration

This preprint presents a coherence-based interpretation of electromagnetic field structure, developed as a continuation of previous work on resonance-based field theory. It also outlines experimentally testable consequences derived from this framework, including a proposed approach to investigating coherence mode interaction under controlled conditions. Within this framework, electric and magnetic fields are described as manifestations of lateral coherence organization, while polarization is reinterpreted as a set of distinct coherence modes with internal phase structure. Building on this perspective, the work examines how interaction between such modes may lead to local redistribution of electromagnetic field intensity. The central focus is not on introducing new fundamental interactions, but on exploring structural consequences within a coherence-based field framework that extends conventional electromagnetic descriptions. In particular, the paper analyzes how coherence mode alignment may influence the formation and concentration of local field maxima, and how such effects may impact interaction with electron-like coherence structures. The proposed effects are subtle and do not imply any violation of energy conservation. Instead, they are interpreted as a redistribution of field structure under specific coherence conditions. Several experimentally accessible situations are discussed, with emphasis on polarization-controlled systems and resonant electromagnetic environments. This work is intended as a conceptual extension of standard electromagnetic theory, offering a structural interpretation that may be relevant for high-precision experiments and systems where coherence and field organization play a central role.