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DETERMINATION OF THE MOBILITY OF FREE CHARGED CARRIERS IN BIOLOGICAL COMPOUNDS

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E. M. TRUKHAN · 1966

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Biological compounds like proteins and DNA can conduct electricity like semiconductors, providing the mechanism for EMF interaction with living cells.

Plain English Summary

Summary written for general audiences

This 1966 study investigated whether proteins and nucleic acids (DNA/RNA components) can conduct electricity like semiconductors. The research examined the mobility of electrical charges in biological compounds, exploring whether living tissues have organized structures that allow electrical current to flow through them.

Why This Matters

This foundational research from 1966 represents early scientific recognition that biological tissues aren't just passive recipients of electromagnetic energy - they're active electrical systems. The study's focus on semiconductor properties in proteins and nucleic acids laid crucial groundwork for understanding how EMF interacts with our bodies at the molecular level. What this means for you: if biological compounds can conduct and channel electrical charges, then external electromagnetic fields don't just bounce off us - they can directly influence the electrical processes that govern cellular function. This research helps explain the biological plausibility behind decades of studies showing EMF effects on everything from DNA repair to cellular communication. The semiconductor properties identified here provide a scientific foundation for why even low-level EMF exposure can have measurable biological consequences.

Exposure Information

Specific exposure levels were not quantified in this study.

Cite This Study
E. M. TRUKHAN (1966). DETERMINATION OF THE MOBILITY OF FREE CHARGED CARRIERS IN BIOLOGICAL COMPOUNDS.
Show BibTeX
@article{determination_of_the_mobility_of_free_charged_carriers_in_biological_compounds_g4981,
  author = {E. M. TRUKHAN},
  title = {DETERMINATION OF THE MOBILITY OF FREE CHARGED CARRIERS IN BIOLOGICAL COMPOUNDS},
  year = {1966},
  
  
}

Quick Questions About This Study

Yes, this 1966 research demonstrated that proteins and nucleic acids (DNA/RNA components) exhibit semiconductor properties, meaning they can conduct electrical charges in organized patterns similar to electronic components.
Conductivity zones are organized pathways within biological molecules where electrical charges can move freely, similar to how electricity flows through circuits. These zones allow EMF to directly interact with cellular processes.
Free charged carriers (electrons and ions) move through biological compounds along organized molecular pathways, creating electrical conductivity that enables cells to respond to external electromagnetic fields and maintain internal electrical processes.
Since biological tissues can conduct electricity, external EMF doesn't just pass through harmlessly - it can directly influence the electrical signals that control cellular functions, DNA repair, and intercellular communication.
The orderly microstructure of proteins and nucleic acids creates specific pathways for electrical conduction. This organized arrangement allows biological molecules to function as natural semiconductors within living cells.