What question did this study set out to answer?

The research aims to determine how radiofrequency fields affect biological radical-pair chemistry.

April 14, 2026Open Access

Radiofrequency Effects on Biological Radical Pairs (AM & WiFi)

Puntos clave

The research aims to determine how radiofrequency fields affect biological radical-pair chemistry.
Utilized quantum spin-dynamics simulations to model interactions.
Compared the effects of 2.4 GHz WiFi and AM broadcasting fields.
Assessed changes in singlet yield due to different radiofrequency exposures.
WiFi fields showed no effect on singlet yields due to high barriers.
AM fields induced over 1% changes in singlet yield within 20 meters of transmitters.
Multi-frequency AM exposure significantly reduced the net effect compared to single-frequency exposure.

Resumen

This study uses quantum spin-dynamics simulations to evaluate whether radiofrequency (RF) fields can perturb biological radical-pair chemistry (FMNH·/O₂⁻·). The model demonstrates that 2.4 GHz WiFi fields cannot influence singlet yields due to severe amplitude, frequency, and coupling barriers. Conversely, AM broadcasting carriers (530–1700 kHz) resonate with the electron Larmor frequency in the geomagnetic field. The simulations show that AM fields can induce >1% changes in singlet yield, but this effect is restricted to distances under 20 meters from high-power transmitters and requires radical-pair lifetimes exceeding 1 μs. Additionally, multi-frequency AM exposure produces destructive quantum interference, significantly reducing the net effect compared to single-station resonance.

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Cite This Study

YH Tiu (Sun,) studied this question.

synapsesocial.com/papers/69ddda0de195c95cdefd77ec https://doi.org/https://doi.org/10.5281/zenodo.19541033

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