Radiation from a charged particle and radiation reaction reexamined

Gupta, Abhinav; Padmanabhan, Τ.

doi:10.1103/physrevd.57.7241

Cited by 28 publications

(38 citation statements)

References 6 publications

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“…One can use the theory to obtain an equation that describes, approximately, the motion of a rigid spherical shell of charge subject to an arbitrary force. This is the Abraham-Lorentz-Dirac (ALD) equation [1][2][3][4][5][6]. This equation, and others like it, is problematic because it is higher than second order in the time derivatives of position, which can lead to problems with causality, and because it has pathological or 'runaway' solutions in which, for example, an object accelerates when no force is applied.…”

Section: Introductionmentioning

confidence: 99%

Reduced-order Abraham-Lorentz-Dirac equation and the consistency of classical electromagnetism

Steane

2015

American Journal of Physics

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It is widely believed that classical electromagnetism is either unphysical or inconsistent, owing to pathological behavior when self-force and radiation reaction are non-negligible. We argue that there is no inconsistency as long as it is recognized that certain types of charge distribution are simply impossible, such as, for example, a point particle with finite charge and finite inertia. This is owing to the fact that negative inertial mass is an unphysical concept in classical physics. It remains useful to obtain an equation of motion for small charged objects that describes their motion to good approximation without requiring knowledge of the charge distribution within the object. We give a simple method to achieve this, leading to a reduced-order form of the Abraham-LorentzDirac equation, essentially as proposed by Eliezer, Landau and Lifshitz, and derived by Ford and O'Connell.

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Section: Introductionmentioning

confidence: 99%

Reduced-order Abraham-Lorentz-Dirac equation and the consistency of classical electromagnetism

Steane

2015

American Journal of Physics

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“…These expressions were found by Fulton and Rohrlich by using the retarded potential method (the use of the retarded potentials actually drops the basis for the first point of Boulware). The same expressions for the electromagnetic fields were also found by Gupta and Padmanabhan, (16) who calculated first the electromagnetic fields in the rest system of the charge, and then transformed them to a system moving in a hyperbolic motion relative to the charge. They also show that by using appropriate transformations to the system of reference of the retarded variables, they recover the equations given in the textbooks (11,13,15) for retarded potentials.…”

Section: The Electric Field Of An Accelerated Chargementioning

confidence: 68%

A Coaccelerated Observer

Harpaz

Soker

2005

Found Phys

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We analyze the situation of an observer coaccelerated relative to a linearly accelerated charge, in order to find whether he can observe the radiation emitted from the accelerated charge. It is found that the seemingly special situation of the coaccelerated observer relative to any other observer, is deduced from a wrong use of the retarded coordinate system, when such a system is inadmissible. It is also found that the coaccelerated observer has no special position other than any other observer, and hence, he can observe any physical events as any other observer.

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“…Such a motion is called "a hyperbolic motion", as it describes a hyperbola in Rindler coordinates (Rindler [5]). We shall use the method suggested by Gupta and Padmanabhan [6], where they calculate first the field equations of a particle (an electric charge) in its own system of reference, and then transform these equations to the system of free space, in which the particle is accelerated. In using this method for the calculation of electric field of an accelerated charge, they recovered the field equations as calculated by Schott [7], and by Fulton and Rohrlich [8].…”

Section: The Reaction Force In a Curved Fieldmentioning

confidence: 99%

“…The gravitational field is calculated first in the rest system of the particle, and then, these equations are transformed to the system in which the particle is accelerated in. These equations, given in cylindrical coordinates (z, ρ, Ɵ), are: (6) where ᶍ ( ) ( 2 2 2 2 2 2 2 is the mass location at t = 0 (the turning point in Rindler coordinates. (Here a is the acceleration).…”

Section: Gravity and Inertial Forcementioning

confidence: 99%

A “Fine Structure Constant” for Inertia

Harpaz¹

2013

IJAA

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We try to find a physical source for the inertial force, which contradicts the acceleration of an object. We find that when an object is accelerated, its gravitational field curves, and the stress force created in this curved field acts on the object against the accelerating force, thus supplying part of the inertial force that contradicts the acceleration. We also find that this force includes a term which is similar to the "fine structure constant" used in quantum mechanics. As well, we find that this term equals unity for a black hole object. Further work is needed in order to find whether the complete inertial force can be found in this way. The experimental results that may prove this approach are still very limited.

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Radiation from a charged particle and radiation reaction reexamined

Cited by 28 publications

References 6 publications

Reduced-order Abraham-Lorentz-Dirac equation and the consistency of classical electromagnetism

Reduced-order Abraham-Lorentz-Dirac equation and the consistency of classical electromagnetism

A Coaccelerated Observer

A “Fine Structure Constant” for Inertia

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