Study Overview
This study by L. Rybina examines the effect of mobile phone electromagnetic field (EMF) radiation on electroencephalogram (EEG) parameters in human subjects. The central question: does mobile phone EMF exposure measurably alter brainwave activity, and if so, does the presence of an Aires resonator modify that effect?
EEG measures electrical activity in the brain as voltage fluctuations across frequency bands. Changes in band power — particularly alpha and theta waves — are associated with shifts in cognitive state, alertness, and neural processing. The study provides a controlled baseline for understanding how ambient device EMF interacts with the brain’s bioelectrical environment.
Methodology
Subjects underwent EEG measurement under three controlled conditions:
- Baseline — no active EMF source present
- EMF exposure — mobile phone active at standard operating proximity, no Aires device
- EMF exposure with Aires — mobile phone active, Aires resonator attached to device
EEG measurements were recorded across the standard frequency bands: delta (0.5–4 Hz), theta (4–8 Hz), alpha (8–13 Hz), and beta (13–30 Hz). Statistical comparison was performed across all three conditions for each band.
Key Findings
Scientific Context
The relationship between radiofrequency EMF and brain electrical activity has been examined in the scientific literature since the widespread adoption of mobile phones. EEG studies occupy a central position in this research because they provide a direct, non-invasive measure of brain bioelectrical state with high temporal resolution.
This study contributes to the Aires research program’s EEG cluster alongside parallel work by M. Sysoev, including a joint Sysoev–Rybina study published in 2025. Taken together, the EEG studies form a consistent picture: mobile phone EMF produces detectable changes in brain electrical activity, and the presence of an Aires resonator is associated with a return toward baseline readings.
The proposed mechanism: the Aires fractal diffraction grating coherently transforms incident EMF rather than blocking or absorbing it (Patent No. 2312384). The transformed field retains the information content of the original signal while reducing its biological disruptiveness — an effect the EEG studies measure as a reduction in deviation from non-EMF baseline.