Hammond versus Ford radiation reaction force with the attractive Coulomb field

Authors

  • G. Ares de Parga ESFM-IPN
  • S. Domínguez-Hernández UPIITA-IPN
  • E. Salinas-Hernández ESCOM-IPN

DOI:

https://doi.org/10.31349/RevMexFis.64.187

Keywords:

radiation reaction, Landau-Lifshitz equation, Ford equation, Hammond equation

Abstract

The classical central field is analyzed within the Hammond theory of radiation reaction force. For the attractive Coulomb field, the trajectories deduced from Ford and Hammond equations are numerically obtained. Ford and Hammond equations are rewritten by using a recent correction to the non-relativistic equations for charged point particles which include a radiation reaction force term. Also, for the attractive Coulomb case, the trajectories are numerically obtained for both corrected equations. A comparison between all these trajectories is made. It is proved that Hammond equation satisfies the constraint proposed by Dirac of getting an equation of motion which should make the electron in the hydrogen atom spiralling inwards and ultimately falling into the nucleus. A further analysis of the applicability of such a theory is described for experiments particularly in Plasma Physics and some comments are made for the generalization of Hammond equation to General Relativity.

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Published

2018-03-14

How to Cite

[1]
G. Ares de Parga, S. Domínguez-Hernández, and E. Salinas-Hernández, “Hammond versus Ford radiation reaction force with the attractive Coulomb field”, Rev. Mex. Fís., vol. 64, no. 2 Mar-Apr, pp. 187–196, Mar. 2018.

Issue

Section

07 Gravitation, Mathematical Physics and Field Theory