Structured Light Phenomena: Resonant Fields in Natural Systems

This study investigates Structured Light Phenomena (SLP) observed under geomagnetically stable, low-turbulence conditions. Documented events revealed reproducible photonic structures exhibiting radial coherence, quantized spectral bands, and phase-locked spatial organization. Analytical models drawn from magnetohydrodynamics, nonlinear optics, and quantum field theory describe structured light phenomena as arising from Alfvénic wave propagation, harmonic resonance structuring, and plasma-field interactions. Spectral decomposition demonstrates coherence with Schumann resonance harmonics and geomagnetic flux boundaries, supporting the interpretation of structured light phenomena as self-organized macroscopic coherence states arising from nonlocal electromagnetic coupling and atmospheric boundary-layer resonance. These findings establish a quantitative framework linking photonic coherence to mesoscale plasma dynamics, geophysical field structures, and resonance-governed energy localization processes.