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Main Author: Damgaard, Mads J.
Format: Preprint
Published: 2023
Subjects:
Online Access:https://arxiv.org/abs/2312.10124
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author Damgaard, Mads J.
author_facet Damgaard, Mads J.
contents We carry out a Dirac sea reinterpretation of a discretized version of the Hamiltonian of quantum electrodynamics (QED), and analyze the perturbed vacuum in the continuum limit. We argue that if certain operators can be shown to be the self-adjoint, the perturbed vacuum will have solutions that converge nicely in this limit to states of the infinitesimal subspace of the Hilbert space spanned by momentum eigenstates whose momenta sum to 0. This convergence allows us to analyze what effect the perturbed vacuum has on the physical states of the system. We then show that the interaction and the interference between the perturbed vacuum and the physical states actually vanish in the continuum limit, due to the fact that the states of the perturbed vacuum only live in this vanishingly small part of the momentum space. We furthermore show that this allows us to remove the terms that perturb the vacuum from the Hamiltonian, without changing the dynamics of the physical states, thus yielding us a well-defined Hamiltonian for the full theory of QED.
format Preprint
id arxiv_https___arxiv_org_abs_2312_10124
institution arXiv
publishDate 2023
record_format arxiv
spellingShingle How the perturbed vacuum might be completely decoupled from all physical states, allowing for a well-defined Hamiltonian formulation of QED
Damgaard, Mads J.
General Physics
We carry out a Dirac sea reinterpretation of a discretized version of the Hamiltonian of quantum electrodynamics (QED), and analyze the perturbed vacuum in the continuum limit. We argue that if certain operators can be shown to be the self-adjoint, the perturbed vacuum will have solutions that converge nicely in this limit to states of the infinitesimal subspace of the Hilbert space spanned by momentum eigenstates whose momenta sum to 0. This convergence allows us to analyze what effect the perturbed vacuum has on the physical states of the system. We then show that the interaction and the interference between the perturbed vacuum and the physical states actually vanish in the continuum limit, due to the fact that the states of the perturbed vacuum only live in this vanishingly small part of the momentum space. We furthermore show that this allows us to remove the terms that perturb the vacuum from the Hamiltonian, without changing the dynamics of the physical states, thus yielding us a well-defined Hamiltonian for the full theory of QED.
title How the perturbed vacuum might be completely decoupled from all physical states, allowing for a well-defined Hamiltonian formulation of QED
topic General Physics
url https://arxiv.org/abs/2312.10124