Dr.-Ing.Konstantin Meyl
Konstantin Meyl is a German physicist and professor emeritus best known for his pioneering work on scalar (longitudinal) wave theory, alternative interpretations of electromagnetism, and experimental extensions of Nikola Tesla’s groundbreaking ideas.
His journey into advanced field physics began with a deep interest in power electronics and electromagnetic phenomena. As former professor at Furtwangen University (HFU), Germany, he developed an extended vortex and field theory that challenges conventional Maxwellian models. Today, Dr. Meyl is driven by the conviction that scalar waves enable efficient, low-loss energy and information transfer, with a sole purpose of creating meaningful connections between theory, experiment, and future technologies.
My Work Experience
For over four decades, my work has focused on the mathematical and experimental validation of longitudinal waves in electrodynamics. By expanding upon classical field theory, I bridge the gap between high-power electronics and the subtle resonance of biological systems.
Professor of Power Electronics
Hochschule Furtwangen University
1986 – 2018 (emeritus)
Head of Scalar Wave Research
1st Transfer Center (1.TZS)
2003 – Present
Developer of Extended Field Theory
Potential Vortex & Longitudinal Waves
1990 - Present
Physicist & Engineer
Electromagnetic & Energy Transmission
1984 – Present
Longitudinal waves connect physics to natural systems From plasma to biological coherence
Field Dynamics
Disturbances oscillate parallel to propagation using compression and rarefaction instead of radiation.
Maxwell Consistency
These arise from scalar electric potential and charge density oscillations in near-field regimes.
Coherent Transport
This creates phase-aligned channels and low-loss coupling mechanisms for stable energy transfer.
Carrier and Information
The longitudinal wave acts as the delivery vehicle while the IR spectrum provides the information.
Longitudinal Waves
Field Disturbance
Oscillates parallel to the direction of propagation, tying together sound, plasma, and charge-density.
Non-Radiative Physics
Near-field and guided regimes that exist within classical Maxwell-consistent frameworks.
Scalar Potential
Utilizes the scalar electric potential E ≠ 0 to enable non-radiative energy transfer.
Today, I am driven by the belief that scalar and longitudinal waves extend classical electromagnetism. This work enables non-radiative, coherent energy and information transfer. It bridges the gap between physics, engineering, and biological systems through the study of resonance and near-field phenomena.
A longitudinal wave is one in which the field disturbance oscillates parallel to the direction of propagation. This unifying feature of compression and rarefaction connects sound waves, plasma density waves, and near-field electric potential waves.
In classical electromagnetism, far-field radiation is transverse. However, longitudinal behavior occurs naturally in near-field and guided regimes. These solutions are consistent with Maxwell’s equations and facilitate energy transfer via resonance, near-field coupling, and guided wave theory.
Charge Displacement
Direct coupling via ionic and aqueous tissue structures.
Density Shifts
Interaction through controlled proton and ion density oscillations.
Molecular Modulation
Influence on the hydrogen-bond network and molecular resonance.
Non-Thermal Delivery
Energy transfer as organization rather than heat dissipation.
Dr. Konstantin Meyl
Longitudinal waves provide a non-radiative, coherent transport mechanism that couples directly to charge density and structure within matter, enabling efficient delivery of modulated spectral information without reliance on transverse electromagnetic radiation.