English

Non-perturbative path integral quantization of the electroweak model: the Maxwell integration

High Energy Physics - Theory 2020-03-04 v1 High Energy Physics - Phenomenology

Abstract

The non-perturbative path integral quantization of the electroweak model is confronted with an apparent instability when integrating over the Maxwell potential AμA_{\mu} due to the fast growth of the box graphs AAAAAAAA and AAAZAAAZ for large amplitude variations of AμA_{\mu}. ZμZ_{\mu} is from the vector part of the weak neutral current. These graphs are unavoidable because they are conditionally convergent and have to be isolated in the model's exact Euclidean one-loop effective action arising from its fermion determinants. A previous QED calculation of the large amplitude variation of its fermion determinant for a class of random potentials showed that the AAAAAAAA box graph cancels in this limit. Using this result it is shown that within the electroweak model large amplitude variations of AμA_{\mu} for fixed ZμZ_{\mu} in a superposition of these fields cancel the AAAAAAAA and AAAZAAAZ graphs, thereby removing an apparent obstacle to the model's non-perturbative quantization. A negative paramagnetic term in the remainder opposes the effective action's growth for such variations. Its calculation requires knowledge of the degeneracy of the bound states of a charged fermion in the four-dimensional magnetic fields generated by the functional measure of AμA_{\mu}.

Cite

@article{arxiv.2002.05385,
  title  = {Non-perturbative path integral quantization of the electroweak model: the Maxwell integration},
  author = {M. P. Fry},
  journal= {arXiv preprint arXiv:2002.05385},
  year   = {2020}
}
R2 v1 2026-06-23T13:40:30.595Z