Radiation-Reaction on the Straight-Line Motion of a Point Charge accelerated by a constant applied Electric Field in an Electromagnetic Bopp-Land\'e-Thomas-Podolsky vacuum

Abstract

The radiation-reaction problem of standard Lorentz electrodynamics with point charges is pathological, standing in contrast to Bopp--Land\'e--Thomas--Podolsky (BLTP) electrodynamics where it is in fact well-defined and calculable, as reported in a previous publication. To demonstrate the viability of BLTP electrodynamics, we consider the BLTP analogue of the radiation reaction of a classical point charge accelerated from rest by a static homogeneous capacitor plate field, and calculate it up to O(4) in a formal expansion about =0 in powers of , Bopp's reciprocal length, a new electrodynamics parameter introduced by BLTP theory. In a paper by Carley and Kiessling (arXiv:2303.01720 [physics.class-ph]) the radiation-reaction corrections to test-particle motion were explicitly computed to O(3), the first non-vanishing order. In this article a crucial question regarding this ``small-'' expansion, raised by Carley and Kiessling, is answered as follows: The motions computed with terms O(3) included are mathematically accurate approximations to physically reasonable solutions of the actual BLTP initial value problem for short times t, viz. when c t 1, where c is the speed of light in vacuo, but their unphysical behavior over much longer times does not accurately approximate the actual BLTP solutions even when the dimensionless parameter e2 / |mb| c2 1, where e is the elementary charge and mb the bare rest mass of the electron. This has the important implication that BLTP electrodynamics remains a viable contender for an accurate classical electrodynamics with point charges that does not suffer from the infinite self-interaction problems of textbook Lorentz electrodynamics with point charges.