Helical Field Topologies and Environmental Current Pollution: Revisiting the Vortex Hypothesis through Classical Electrodynamics

Kim Horsevad

Abstract: This article examines the emergence of vortex-like electromagnetic field structures within Maxwell?s classical electrodynamics, focusing on conditions that induce rotational behavior in the Umov-Poynting vector. The study identifies how phase relationships between orthogonal electric and magnetic field components give rise to helical topologies. Building upon this model, the paper explores four classical mechanisms by which such topologies may interact with biological systems, including interfacial electrokinetics, magnetochiral anisotropy, spin-selective electron transport, and electromagnetic torque. These interactions are contextualized through environmental current pollution, particularly in industrial and agricultural settings. The work bridges theoretical constructs with empirical evidence and proposes a set of testable predictions relevant for environmental health and bioelectromagnetic studies.

Keywords: Stray current, vortex field, environmental current pollution, biological interaction, Maxwellian electrodynamics

How to Cite?: Kim Horsevad, "Helical Field Topologies and Environmental Current Pollution: Revisiting the Vortex Hypothesis through Classical Electrodynamics", Volume 14 Issue 11, November 2025, International Journal of Science and Research (IJSR), Pages: 617-626, https://www.ijsr.net/getabstract.php?paperid=SR251107192341, DOI: https://dx.doi.org/10.21275/SR251107192341