Alternative routes to the retarded potentials

Heras, Ricardo

doi:10.1088/1361-6404/aa7f18

Cited by 11 publications

(17 citation statements)

References 25 publications

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“…In the cited papers it has been argued that charge conservation and causality, respectively represented by the local continuity equation and the retarded time are the cornerstones on which Maxwell's equations are based and therefore they can be considered to be the two fundamental postulates for these equations. It is worth mentioning that although Maxwell's equations are universally accepted, the question of what their fundamental physical postulates are remains a topic of discussion and debate [13,14,15,16,17,18,19]. The derivation of Maxwell's equations presented here in its three-dimensional and fourdimensional versions, which considers potentials as primary quantities and fields as derived quantities, may be useful to grasp the background of Maxwell's theory and may be presented in undergraduate courses of electromagnetism.…”

Section: Introductionmentioning

confidence: 99%

“…A question arises: could there be a set of first order field equations + Equation (7) is proved in reference [6]. As pointed out in reference [18] this identity is true for functions F such that the quantities [F ]/R have not the form…”

Section: Introducing the Potentials φ And A Before The Fields E And Bmentioning

confidence: 99%

“…We have obtained two equivalent versions of electromagnetic field equations. The first one is represented by equations (6) and (8) which are expressed in terms of the retarded scalar and vector potentials defined in (5) and the second one is represented by equations (13)- (16) which are expressed in terms of the retarded fields defined by equations (17) and (18). This second version of the equations is identified with the familiar Maxwell's equations.…”

Section: Introducing the Potentials φ And A Before The Fields E And Bmentioning

confidence: 99%

“…where (E) i and (B) k are the Cartesian components of the fields E and B, then (29), (31) and (32) reproduce (13)- (18). We have obtained two equivalent covariant versions of the electromagnetic field equations in the Minkowski spacetime.…”

Section: Introducing the Four-potential A µ Before The Electromagnetimentioning

confidence: 99%

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On Feynman’s handwritten notes on electromagnetism and the idea of introducing potentials before fields

Heras¹,

Heras²

2020

Eur. J. Phys.

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In his recently discovered handwritten notes on "An alternate way to handle electrodynamics" dated on 1963, Richard P. Feynman speculated with the idea of getting the inhomogeneous Maxwell's equations for the electric and magnetic fields from the wave equation for the vector potential. With the aim of implementing this pedagogically interesting idea, we develop in this paper the approach of introducing the scalar and vector potentials before the electric and magnetic fields. We consider the charge conservation expressed through the continuity equation as a basic axiom and make a heuristic handle of this equation to obtain the retarded scalar and vector potentials, whose wave equations yield the homogeneous and inhomogeneous Maxwell's equations. We also show how this axiomatic-heuristic procedure to obtain Maxwell's equations can be formulated covariantly in the Minkowski spacetime.

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Section: Introductionmentioning

confidence: 99%

Section: Introducing the Potentials φ And A Before The Fields E And Bmentioning

confidence: 99%

Section: Introducing the Potentials φ And A Before The Fields E And Bmentioning

confidence: 99%

Section: Introducing the Four-potential A µ Before The Electromagnetimentioning

confidence: 99%

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On Feynman’s handwritten notes on electromagnetism and the idea of introducing potentials before fields

Heras¹,

Heras²

2020

Eur. J. Phys.

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“…The electromagnetic interactions are calculated by a set of Maxwell equations in rectangular coordinates. Usually, the retarded potential is used for the special relativity [39,40]. Although this potential is difficult to solve for a system with a large number of particles, such as N > 10 5 particles, the large Coulomb potential field and the transverse electric field are separated.…”

Section: Motion and Maxwell Field Equationsmentioning

confidence: 99%

Relativistic and electromagnetic molecular dynamics simulations for a carbon–gold nanotube accelerator

Tanaka

Murakami

2019

Computer Physics Communications

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Relativistic molecular dynamics are described in ultra-high temperature and MeV energy behaviors. In strongly-coupled systems, the Coulomb electrostatic field is collected in the infinite space, and the electromagnetic fields are added in the coordinate space. Separation of the electromagnetic and electrostatic electric fields is a good approximation for short time periods. For a numerical application, a nanotube accelerator under an E × B pulse is studied. Positive ions are accelerated in the parallel direction, whereas the electrons proceed in the perpendicular direction. Rapid expansion to infinite space and short-range electromagnetic radiation cooperate for large intensities. At 10 22 W/cm 2 , pulsation oscillations for gold and carbon ions flare up and electrons acquire the relativistic velocities. They are observed in relativistic molecular dynamics simulation.

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