 01419 Tepper L. Gill, Woodford W. Zachary and James Lindesay
 The Classical Electron Problem
(415K, pdf)
Nov 9, 01

Abstract ,
Paper (src),
View paper
(auto. generated pdf),
Index
of related papers

Abstract. In this paper, we construct a parallel image of the conventional Maxwell theory by replacing the observertime by the propertime of the source. This formulation is mathematically, but not physically, equivalent to the conventional form. The change induces a new symmetry group which is distinct from, but closely related to the Lorentz group, and fixes the clock of the source for all observers. The new wave equation contains an additional term (dissipative), which arises instantaneously with
acceleration. This shows that the origin of radiation reaction is not the action of a "charge" on itself but arises from inertial resistance to changes in motion. This dissipative term is equivalent to an effective mass so that classical radiation has both a massless and a massive part. Hence, at the local level the theory is one of particles and fields but there is no selfenergy divergence (nor any of the other problems).
We also show that, for any closed system of particles, there is a global inertial frame and unique (invariant) global propertime (for each observer) from which to observe the system. This global clock is intrinsically related to the proper clocks of the individual particles and provides a unique definition of simultaneity for all events associated with the system. We suggest that this clock is the historical clock of Horwitz, Piron, and Fanchi. At this level, the theory is of the actionatadistance type and the absorption hypothesis of Wheeler and Feynman follows from global conservation of energy.
 Files:
01419.src(
01419.keywords ,
ed2tex%20typeset.pdf.mm )