Covariant operator formalism for higher derivative systems: Vector spin-$0$ dual model as a prelude to generalized QED$_4$
Abstract
In this work we extend the Kugo-Ojima-Nakanishi covariant operator formalism to quantize two higher derivative systems, considering their extended phase space structures. More specifically, the one describing spin-$0$ particles by a vector field and the generalized electrodynamics. We investigate the commutator structure of these theories and present the definition of their physical Hilbert subspaces. Remarkably, the correspondence principle demands a higher derivative structure for the auxiliary field Lagrangian. The first model presents a reducible gauge symmetry implying the necessity of two sets of auxiliary fields. The massless limit is also carefully analyzed. For the case of the generalized QED$_4$, we derive a set of suitable definitions for the physical Hilbert subspace to eliminate contributions from spurious modes and the problematic negative norm transverse excitations. However, preliminary discussions on the interacting regime are also developed to show that, in this case, the states with transverse ghost modes can be produced from ghost-free initial ones, meaning that they cannot be decoupled. Additionally, we reveal the very source of renormalization improvements in these kinds of theories and also establish a suitable specific interacting model compatible with a time-invariant positive norm subspace.
- Publication:
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arXiv e-prints
- Pub Date:
- April 2024
- DOI:
- 10.48550/arXiv.2404.11805
- arXiv:
- arXiv:2404.11805
- Bibcode:
- 2024arXiv240411805D
- Keywords:
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- High Energy Physics - Theory