Chemical polarization effects of electromagnetic field radiation from the novel 5G network deployment at ultra high frequency

Abstract

Overview

The study explores the impact of non-ionizing, non-visible radiation emitted by the novel 5G network, particularly at ultra-high frequencies. This type of radiation was found to significantly affect the natural structure of the human body by heating and altering cellular and tissue orientation.

Findings

• The ultra-high frequency magnetic fields can induce currents in the human body, which is naturally dipolar. The extent of these effects is influenced by the strength of the external magnetic field.
• It was observed that the radiofrequency radiation from 5G network installations, particularly at frequencies above 20 GHz, could heat human body tissues. This heating could lead to a range of polarization effects including dielectric, ionic, interfacial, and orientational polarization.
• The levels of electromagnetic fields under previous technology (4G) and under scenarios testing 5G were compared. The research suggested that while the exposure levels under usual conditions are negligible, the specific conditions above 20GHz present significant health risks.

Conclusion

The biological characteristics of human tissues under various electromagnetic emissions were examined to understand their susceptibility to frequency-induced changes. It is crucial that the frequency distributions used in 5G network deployments are managed to prevent adverse health impacts, including the noted polarizations and heating effects. Applying caution in the deployment of 5G technology under frequencies higher than 20 GHz is essential to mitigate these health risks.