About us

Born in France

More than 15 years ago ...

we pioneered a materials-science approach to everyday electromagnetic fields

For more than fifteen years, our team in France has explored how advanced materials can shape the everyday electromagnetic environment created by connected devices phones, tablets, routers, wearables, and beyond. We started with a simple promise: bring rigorous materials science to a problem that affects modern life, and make the solution effortless to wear and easy to love.

Valençay

Our Origin

The company was born in Valencay from one person’s real-world challenge: heightened sensitivity to electromagnetic fields (EMF). Confronted with a lack of effective options at the time, our founder devoted years to researching material properties and wave–matter interactions. That pursuit led to a family of passive, non-powered “chips” designed to harmonize the near-field behavior of everyday electronics.

30 years of scientific research

22 international patents

vitality and live blood cell tests

Born from hope

Our Technology

Our devices combine engineered dielectric composites with micro-scale resonant geometries (think metamaterial-inspired patterns).

By locally perturbing impedance and tuning loss characteristics across relevant RF bands (including 5G), the chips help:

  • smooth steep near-field gradients,
  • damp high-frequency transients and spurious emissions,
  • promote more coherent field distributions around the device.

In plain terms: they stabilize the local RF environment right where your body interacts with it.

Our Research Process

We treat validation as a multi-layer pipeline:

1. Electromagnetic Characterization
Near-field scanning, power-density mapping, and vector-network analysis (S-parameters) to quantify coupling, resonance behavior, and damping effects.

2. Modeling & Simulation
Computational studies to visualize field redistribution and assess parameters related to SAR patterns under defined conditions.

3. In-Vitro & Exploratory Physiology
Microscopy-based observations of hemorheology proxies (such as red-blood-cell aggregation/deformability) during controlled mobile-call exposure scenarios. These laboratory observations help us refine designs for stability and coherence.

4. Field Pilots
Real-world pilots in agriculture and animal husbandry have reported encouraging signals (e.g., yield/quality metrics). We continue to design better-controlled and blinded trials to probe mechanisms and reproducibility.

5. EEG Mapping during calls
Electroencephalography recorded while on a phone call (with/without the device) to identify which brain regions show the strongest modulation. Analyses include spectral power, topographic maps, and connectivity metrics to guide design priorities.

We’re committed to transparency: refining protocols, inviting third-party labs, and publishing results summaries where possible.