Engineering Bulletin of Don, No. 4 (2018) — ivdon.ru/ru/magazine/archive/n4y2018/5278
Overview
This 2018 peer-reviewed study from the Engineering Bulletin of Don presents a mathematical model of how the Aires resonator physically interacts with high-frequency electromagnetic radiation. Using computer simulation, the authors demonstrate that when a 6 GHz WiFi signal strikes the Aires C20S5G resonator, the device does not simply block or scatter the signal — it converts incoming periodic radiation into new periodic signals at specific frequencies (6.85 GHz and 5.38 GHz) that may interact with biological cell organelles.
This is direct evidence for the mechanism underlying Aires’ approach to EMF modulation: the resonator acts as a frequency converter, transforming non-native electromagnetic patterns into structured, periodic radiation.
Authors and Affiliations
- I.N. Serov — Aires Human Genome Research Foundation, St. Petersburg
- K.A. Korshunov — Aires Human Genome Research Foundation, St. Petersburg
- A.V. Kopyltsov — St. Petersburg State Electrotechnical University “LETI” (V.I. Ulyanov); St. Petersburg State University of Aerospace Instrumentation (GUAP)
Published: Engineering Bulletin of Don, No. 4, 2018
Archive URL: ivdon.ru/ru/magazine/archive/n4y2018/5278
Background
The Aires resonator (C20S5G) consists of a silicon substrate 0.5 mm thick with a self-affine ring diffraction grating — circular grooves etched into the surface, forming rectangular slots 0.2 μm wide and 0.6 μm deep. The completed resonator (7.4 mm diameter) contains 4,084,101 concentric circles of varying diameter. Prior work by this research group had established that irradiating structured silicon surfaces with electromagnetic radiation produces varied field distributions depending on resonator geometry. The present study constructs a rigorous mathematical model to calculate precisely what happens to WiFi-frequency radiation when it encounters this structure.
Mathematical Model
The model treats the radiation source as a hemisphere of radius R (much larger than the resonator diameter), emitting monochromatic waves at ω = 6 GHz (WiFi frequency). Radiation propagates along path D→B→C→A, where D is the source point, C is a point on the resonator surface (either on the silicon plateau or in a groove), and A is the measurement point above the resonator.
The flat resonator surface is divided into square cells (step h = 24 μm) and the measurement space above it into cubic cells. At each time step Δt, the electric field strength E at every measurement point is calculated as the superposition of all reflected (from plateau surfaces) and diffracted (from groove slots) contributions:
E = Ereflected + Ediffracted
Diffraction at the slots uses the standard single-slit formula accounting for slit width b, wavelength λ, and diffraction angle β. This produces a four-dimensional output matrix of field strength as a function of position and time.
Calculation parameters:
- Incident frequency: ω = 6 GHz (WiFi)
- Incident field strength: E₀ = 10 V/m
- Source-to-resonator distance: 10 m
- Resonator: 7.6 × 7.6 × 0.5 mm, grooves 0.2 μm wide × 0.6 μm deep
- Interaction time: t = 1 s
Results
Computer simulation revealed that the electric field strength E above the resonator’s central region oscillates with a complex, time-dependent structure. Analysis at two different time-step resolutions showed:
- At 6.85 GHz and 5.38 GHz: the field oscillates periodically — stable, structured emissions at these two specific frequencies
- At all other frequencies: the field changes non-periodically, in a chaotic manner
When irradiated by 6 GHz WiFi, the Aires C20S5G resonator generates stable periodic emissions at 6.85 GHz and 5.38 GHz while converting energy at other frequencies into non-periodic, chaotic forms.
Conclusions
“The Aires (C20S5G) resonator can be regarded as a converter of incident periodic irradiation into other periodic radiations, with frequencies that can be resonant for some molecules and components of cells in living organisms. By varying groove depth and width, resonator size, and other structural parameters, it is possible to target specific frequencies to which particular cell organelles are sensitive.”
Significance
This paper provides the theoretical physics foundation for understanding what the Aires resonator physically does to electromagnetic radiation. Three conclusions stand out:
- The device is not a shield. It does not block or absorb WiFi radiation — it converts it. The carrier signal remains physically unchanged; what changes is the electromagnetic pattern surrounding the device.
- The output frequencies are biologically relevant. The generated 6.85 GHz and 5.38 GHz signals fall within ranges known to interact with cellular structures.
- The mechanism is physically measurable. Frequency conversion via diffraction is a standard physical phenomenon, independently validated by Lukyanov et al. 2022 (Springer) and VGTU 2016.
Full Citation
Serov I.N., Korshunov K.A., Kopyltsov A.V. “Mathematical Modeling of the Interaction of a Ring-Structured Surface with High-Frequency Electromagnetic Radiation” // Engineering Bulletin of Don, No. 4, 2018. URL: ivdon.ru/ru/magazine/archive/n4y2018/5278
Original language: Russian. English translation by Aires Research Team.
Research Foundation: Physics Validation
This mathematical modeling study is part of the physics validation track addressing: does the Aires resonator physically alter EMF?
VGTU 2016 (physical resonator testing) — engineers reproduced the mathematical findings in physical hardware
Lukyanov et al. 2022 (Springer) — independent validation via semiconductor wafer modeling
Biological outcomes: VMA 2024 (EEG/ECG) — Sysoev & Rybina 2025 — Datova 2013 (HRV)
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