The Use of Finite Differences on Electric Currents Gives Credit to Coulomb‟s Law as Causing Electromagnetic Forces, thereby Explaining Electromagnetic Induction

Jonson, Jan Olof

doi:10.7763/ijmo.2013.v3.301

Cited by 4 publications

(5 citation statements)

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“…It may best be treated as a coupling constant in that case. It has been shown elsewhere [6], [7], [12] that this analysis applies to the induction of a current in a secondary circuit.…”

Section: An Alternative Model Explaining Electromagnetic Inductionmentioning

confidence: 99%

“…Ampère), rather than presenting convincing proofs corroborating their own standpoints. However, finally, Jonson has made a successful effort to derive electromagnetic induction, by applying the Continuity Equation of Electricity [6], [7]. The basic reason for daring to use Coulomb's law straightforwardly on moving charges is the discovery that the different propagation delay of the immobile lattice ions and the mobile electrons in a metallic conductor, gives rise to a net Coulomb field that has been misunderstood as a separate 'Lorentz force' [8].…”

Section: Introductionmentioning

confidence: 99%

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The Claim that Neumann’s Induction Law Is Consistent with Ampère’s Law Rejected

Jonson¹

2014

IJMO

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Abstract-There have been made several efforts to link Ampère´s law to different parts of electromagnetic field theory In this paper Neumann's effort to make his induction law to appear to be consistent with Ampère's law will be studied thoroughly., Since there exists a concept, named "Ampere-Neumann electrodynamics", it has been regarded as necessary to analyze how Neumann derives the connection between induction and Ampère's force law. One conspicuous thing is that he by the electromotive force of the secondary loop is meaning a physical, mechanical force, contrary to what has usually has been understood as an induced voltage. This makes it possible for him to claim his ideas to be consistent with Ampère's law. On the contrary, recent papers have convincingly shown that the Continuity Equation of Electricity is able to explain, how a current is being induced in a secondary circuit, due to an alternate current in the primary circuit. Earlier discoveries that Coulomb's law is able to account for electromagnetic forces, without involving magnetic fields, provides the conceptual background, which makes the use of magnetic fields unnecessary also in connection with induction.Index Terms-Neumann's induction law, ampère's law, faraday's law of induction, grassmann's force law, coulomb's law.

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“…It may best be treated as a coupling constant in that case. It has been shown elsewhere [6], [7], [12] that this analysis applies to the induction of a current in a secondary circuit.…”

Section: An Alternative Model Explaining Electromagnetic Inductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

The Claim that Neumann’s Induction Law Is Consistent with Ampère’s Law Rejected

Jonson¹

2014

IJMO

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“…In several papers evidence has been presented that is able to refute the widely recognized electromagnetic theory of today [1][2][3][4][5]. One such fundamental law is Lorentz' force law.…”

Section: Introductionmentioning

confidence: 99%

“…In fact, it has been possible to explain this, too, using basically Coulomb's law [15][16][17][18]. One may mention also electromagnetic induction [3][4][5].…”

Section: Introductionmentioning

confidence: 99%

The Electromagnetic Force between Two Parallel Current Conductors Explained Using Coulomb’s Law

Jonson¹

2015

Advanced Electromagnetic Waves

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In this book chapter the electromagnetic force between two parallel electric conductors has been derived, applying thereby the effects of propagation delay and the Special Relativity theory, taking thereby also into count the thus far neglected effects introduced by the voltage sources of both circuits. This has been done for a specific case consisting of two rectangular circuits, aligned to each other along one of the long sides, at a distance that is short compared to the long sides. The intention in doing so is to make a meaningful application of the concept of two parallel conductors of infinite length , so that it is possible to make a complete calculation of the force between the two circuits, avoiding thus making a vague claim as for example Maxwell, saying that the other parts of the conductors do not contribute to the force. What is radically new in this interpretation is that it is Coulomb s law that is responsible for the force.

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“…Since Coulomb"s law is very well corroborated with respect to stationary charges [5,6], it follows naturally to examine whether it would be possible to derive other effects of electric charges using the same law. In more recent work, it has been possible to derive the force between electric currents [7], the induction law [8][9][10], and the basic planetary atom model with respect to the excitation of electromagnetic radiation [11][12][13][14]. It has also been possible to falsify the Lorentz Force Law, whereas Coulomb"s law succeeds in giving credit to the electromagnetic force, provided the effects of propagation delay are correctly taken into account [7].…”

mentioning

confidence: 99%

Extended Use of Coulomb’s Law in Relation to Established Laws within Electromagnetism

Jonson¹

2016

JBAP

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Abstract-The competence of the basically electrostatic Coulomb's Law has historically been assumed to be restricted to pure electrostatics. As soon as electric charges were studied in motion, new sets of laws were introduced to explain the electromagnetic forces that are impelled by the motion. Among these new laws are Neumann's law of induction, Grassmann's force law, Lorentz' force law, and Ampère's force law. Furthermore, the difficulties in explaining the nature of light have given rise to the so-called wave-particle paradox. 1997 was the first year of the public circulation of research results that succeeded in showing that the basic force behind cases involving electricity or, more precisely, electromagnetism, can be derived from electrostatics. The aim of this article is to unify the results of existing theoretical research that discusses problems inherent within the prevailing standpoint on electromagnetism. In this paper, the conflict between the Lorentz Force Law and Ampère's Law is explored. Simultaneously, an alternative based strictly on electrostatics is closely examined. The very limited interest in this field of research, however, makes the amount of existing papers rather limited. The present study's new intervention is as follows: The so-called Ampè re forces between collinear currents, as in Ampère's bridge and in exploding wires, have been explained to be due to electrostatics, provided that the propagation delay dependant on the motion of charges is correctly taken into account. The Lorentz Force Law fails in this case. Additionally, electromagnetic induction can be explained by applying electrostatics, whereas the induction law fails. Light on the orbit electrons in the atoms involved in excitation and de-excitation of states can be explained using Coulomb's law (this has been widely disputed within science). The appearance of light at an atom hit by electromagnetic radiation can be shown to constitute a case of electromagnetic induction. The present study's conclusion is therefore that Coulomb's law is the only necessary force law within electromagnetism.

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The Use of Finite Differences on Electric Currents Gives Credit to Coulomb‟s Law as Causing Electromagnetic Forces, thereby Explaining Electromagnetic Induction

Cited by 4 publications

References 4 publications

The Claim that Neumann’s Induction Law Is Consistent with Ampère’s Law Rejected

The Claim that Neumann’s Induction Law Is Consistent with Ampère’s Law Rejected

The Electromagnetic Force between Two Parallel Current Conductors Explained Using Coulomb’s Law

Extended Use of Coulomb’s Law in Relation to Established Laws within Electromagnetism

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