| [1] | Steffen Kühn: Weber–Maxwell electrodynamics: classical electromagnetism in its most compact and pure form. Electromagnetics, 2024 |
| [2] | Steffen Kühn: The Importance of Weber–Maxwell Electrodynamics in Electrical Engineering. IEEE Transactions on Antennas and Propagation, 2023 |
| [3] | Wilhelm Weber: Wilhelm Weber's Main Works in Electrodynamics Translated into English. Volume I: Gauss und Weber's Absolute System of Units. Apeiron Montreal, 2021 |
| [4] | Wilhelm Weber: Wilhelm Weber's Main Works in Electrodynamics Translated into English. Volume II: Weber's Fundamental Force and the Unification of the Laws of Coulomb, Ampere and Faraday. Apeiron Montreal, 2021 |
| [5] | Wilhelm Weber: Wilhelm Weber's Main Works in Electrodynamics Translated into English. Volume III: Measurement of Weber's Constant c, Diamagnetism, the Telegraph Equation and the Propagation of Electric Waves at Light Velocity. Apeiron Montreal, 2021 |
| [6] | Wilhelm Weber: Wilhelm Weber's Main Works in Electrodynamics Translated into English. Volume IV: Conservation of Energy, Weber's Planetray Model of the Atom and the Unification of Electromagnetism and Gravitation. Apeiron Montreal, 2021 |
| [7] | Wesley, J. P.: Weber electrodynamics, Part I. General theory, steady current effects. Foundations of Physics Letters, 1990 |
| [8] | A. K. T. Assis: Weber's Force versus Lorentz's force. Physics Essays, 1995 |
| [9] | A. K. T. Assis and Marcelo A. Bueno: Equivalence Between Ampere and Grassmann's Forces. IEEE Transactions On Magnetics, 1996 |
| [10] | A. K. T. Assis and H. T. Silva: Comparison between Weber’s electrodynamics and classical electrodynamics. Pramana, 2000 |
| [11] | Anonymous: Advances in Weber and Maxwell electrodynamics. Amazon Fulfillment, 2018 |
| [12] | J. P. M. C. Chaib and F. M. S. Lima: Resuming Ampère’s experimental investigation of the validity of Newton’s third law in electrodynamics. Annales de la Fondation Louis de Broglie, 2020 |
| [13] | Martin Tajmar and Marcel Weikert: Evaluation of the Influence of a Field-Less Electrostatic Potential on Electron Beam Deflection as Predicted by Weber Electrodynamics. Progress In Electromagnetics Research M, 2021 |
| [14] | Baumgärtel, Christof and Maher, Simon: Foundations of Electromagnetism: A Review of Wilhelm Weber's Electrodynamic Force Law. Foundations, 2022 |
| [15] | Montes, Juan Manuel: On the Modernisation of Weber's Electrodynamics. Magnetism, 2023 |
| [16] | A. K. T. Assis and J. P. M. C. Chaib: Ampère's electrodynamics: Analysis of the meaning and evolution of Ampère's force between current elements, together with a complete translation of his masterpiece: Theory of electrodynamic phenomena, uniquely deduced from experience. C. Roy Keys Inc., 2015 |
| [17] | Graneau, N., Phipps Jr, T. Roscoe, D.: An experimental confirmation of longitudinal electrodynamic forces. The European Physical Journal D - Atomic, Molecular, Optical and Plasma Physics, 2001 |
| [18] | Steffen Kühn: Experimental investigation of an unusual induction effect and its interpretation as a necessary consequence of Weber electrodynamics. Journal of Electrical Engineering, 2021 |
| [19] | Baumgärtel, Christof and Maher, Simon: Resolving the paradox of unipolar induction: new experimental evidence on the influence of the test circuit. Scientific Reports, 2022 |
| [20] | Steffen Kühn: Inhomogeneous wave equation, Liénard-Wiechert potentials, and Hertzian dipoles in Weber electrodynamics. Electromagnetics, 2023 |
| [21] | Steffen Kühn: Interpretation of the solution of Maxwell's equations for a moving Hertzian dipole. Progress In Electromagnetics Research C, 2023 |
| [22] | Steffen Kühn: Analytical solution of Maxwell's equations for arbitrarily moving point charges and its application for ultra-fast, high-quality simulation of electromagnetic fields. Techrxiv, 2023 |
| [23] | Peter Graneau, Neal Graneau: Newtonian Electrodynamics. World Scientific, 1996 |
| [24] | Jackson, John David: Classical electrodynamics. Wiley, 1999 |
