The Pollinator Protection and Electromagnetic Ecology Framework: 6G and Terahertz Radiation Effects on Bee Magnetoreception, the Global Food Security Cascade, Presignal Field Monitoring, Biomimetic Floral Signal Guidance Arrays, and Counter-Rotating Mobius Wind Architecture for Agricultural Microclimate Management

Honeybees and the broader pollinator community underpin approximately 35 percent of global food crop production. Between June 2024 and March 2025, the United States lost more than 1.7 million bee colonies — over 60 percent of commercial beekeeping stock — the most severe pollinator die-off in recorded history. The dominant explanatory framework attributes this collapse to pesticides, parasitic mites, habitat loss, and nutritional stress. These factors are real and documented. They are not complete. This paper applies the Presignal Subtraction Methodology to the pollinator collapse problem and identifies a systematically unmeasured variable: the cumulative electromagnetic field environment at ground level and flower height in agricultural and habitat zones, and specifically the emerging exposure from 5G and pre-deployment 6G terahertz frequency radiation. Peer-reviewed physics simulations demonstrate that insect RF power absorption increases between 3 and 370 percent as frequency shifts above 6 GHz — precisely the spectrum 6G occupies. Bees navigate using cryptochrome-based magnetoreceptors tuned to Earth's natural electromagnetic field; these receptors are demonstrably sensitive to anthropogenic electromagnetic disruption. The field-realistic biological safety data required to assess this exposure does not exist. Regulators are approving global 6G deployment into a confirmed knowledge vacuum. This paper presents five integrated response frameworks: (1) a Presignal distributed electromagnetic monitoring array measuring real pollinator-height field exposure in agricultural corridors; (2) underground and substrate-based signal routing to eliminate surface-level terahertz emission in sensitive habitat zones; (3) LiFi and free-space optical communication as zero-RF surface data links; (4) a biomimetic electrostatic floral signal guidance array that mimics natural flower electric field signatures to actively direct pollinators toward high-yield crop zones during peak bloom; and (5) a counter-rotating Mobius-profile wind blade architecture that generates structured toroidal cooling airflow for agricultural microclimate management while eliminating conventional turbine electromagnetic pulse signatures and vibrational ground stress on soil-nesting pollinators. This is the first unified pollinator electromagnetic ecology and active habitat management system in the published literature.