Unphysical and physical(?) solutions of the Lorentz-Dirac equation

Foundations of Physics 23 (8):1093-1119 (1993)
  Copy   BIBTEX

Abstract

A simple proof of a weak version of Eliezer's theorem on unphysical solutions of the Lorentz-Dirac equation is given. This version concerns a free particle scattered by a spatially localized electric field in one space dimension. (The solutions are also solutions in three space dimensions.) It establishes that for certain physically reasonable localized fields, all solutions which are free (i.e., unaccelerated) before they enter the field have unbounded proper acceleration and velocity asymptotic to that of light in the future. For any given initial velocity, the fields yielding this unphysical behavior can be arbitrarily weak. The result is then extended to a class of static fields which need not be spatially localized, including Coulomb fields. For this case the same conclusion is obtained omitting the assumption that the particle be free in the past.The rest of the paper discusses solutions to the localized field problem which are assumed free in the future rather than the past. Some strange features of these solutions are noted. The possibility of experimentally detecting deviations from the Coulomb law for a particle obeying the Lorentz-Dirac equation is discussed

Categories

Keywords

Reprint years

DOI

10.1007/bf00732415

Links

PhilArchive



    Upload a copy of this work     Papers currently archived: 91,783

External links

Setup an account with your affiliations in order to access resources via your University's proxy server

Through your library

My notes

Similar books and articles

Remarks on the physical meaning of the Lorentz-Dirac equation.E. Comay - 1993 - Foundations of Physics 23 (8):1121-1136.
Nonuniqueness of the “physical” acceleration for the Lorentz-Dirac equation.Stephen Parrott & Daniel J. Endres - 1995 - Foundations of Physics 25 (3):441-464.
Four-space formulation of Dirac's equation.A. B. Evans - 1990 - Foundations of Physics 20 (3):309-335.
The extended classical charged particle.R. G. Beil - 1989 - Foundations of Physics 19 (3):319-338.
Charge Conservation, Klein’s Paradox and the Concept of Paulions in the Dirac Electron Theory: New Results for the Dirac Equation in External Fields.Y. V. Kononets - 2010 - Foundations of Physics 40 (5):545-572.
Radiation Reaction of the Classical Off-Shell Relativistic Charged Particle.O. Oron & L. P. Horwitz - 2001 - Foundations of Physics 31 (6):951-966.
Field theory onR× S 3 topology. III: The Dirac equation. [REVIEW]M. Carmeli & S. Malin - 1985 - Foundations of Physics 15 (10):1019-1029.
Chiral two-component spinors and the factorization of Kramers's equation.L. C. Biedenharn & L. P. Horwitz - 1984 - Foundations of Physics 14 (10):953-961.
Stochastic equations of motion with damping.John E. Krizan - 1979 - Foundations of Physics 9 (9-10):695-705.
Particle Spectrum Implied by the Dirac Equation.R. H. Good - 1998 - Foundations of Physics 28 (7):1137-1156.
Coulomb Potential from Lorentz Invariance in N Dimensions.Martin Land - 2007 - Foundations of Physics 37 (4-5):597-631.
From Time Inversion to Nonlinear QED.Wei Min Jin - 2000 - Foundations of Physics 30 (11):1943-1973.
Uniformly Accelerated Charge in a Quantum Field: From Radiation Reaction to Unruh Effect. [REVIEW]Philip R. Johnson & B. L. Hu - 2005 - Foundations of Physics 35 (7):1117-1147.
Generalized Dirac Equation with Induced Energy-Dependent Potential via Simple Similarity Transformation and Asymptotic Iteration Methods.T. Barakat & H. A. Alhendi - 2013 - Foundations of Physics 43 (10):1171-1181.

Analytics

Added to PP
2013-11-22

Downloads
16 (#904,500)

6 months
7 (#425,099)

Historical graph of downloads
How can I increase my downloads?

Citations of this work

Remarks on the physical meaning of the Lorentz-Dirac equation.E. Comay - 1993 - Foundations of Physics 23 (8):1121-1136.

Add more citations

References found in this work

No references found.

Add more references