Eliminating Electron Self-repulsion

Foundations of Physics 53 (4):1-15 (2023)
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Abstract

Problems of self-interaction arise in both classical and quantum field theories. To understand how such problems are to be addressed in a quantum theory of the Dirac and electromagnetic fields (quantum electrodynamics), we can start by analyzing a classical theory of these fields. In such a classical field theory, the electron has a spread-out distribution of charge that avoids some of the problems of self-interaction facing point charge models. However, there remains the problem that the electron will experience self-repulsion. This self-repulsion cannot be eliminated within classical field theory without also losing Coulomb interactions between distinct particles. But, electron self-repulsion can be eliminated from quantum electrodynamics in the Coulomb gauge by fully normal-ordering the Coulomb term in the Hamiltonian. After normal-ordering, the Coulomb term contains pieces describing attraction and repulsion between distinct particles and also pieces describing particle creation and annihilation, but no pieces describing self-repulsion.

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10.1007/s10701-023-00702-0

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Author's Profile

Charles Sebens
California Institute of Technology

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The fundamentality of fields.Charles T. Sebens - 2022 - Synthese 200 (5):1-28.

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References found in this work

The fate of 'particles' in quantum field theories with interactions.Doreen Fraser - 2008 - Studies in History and Philosophy of Science Part B: Studies in History and Philosophy of Modern Physics 39 (4):841-859.
Against fields.Dustin Lazarovici - 2017 - European Journal for Philosophy of Science 8 (2):145-170.
Is classical electrodynamics an inconsistent theory?Gordon Belot - 2007 - Canadian Journal of Philosophy 37 (2):263-282.

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