Abstract
Quantum field theory in curved spacetimes suffers in general from an infinite ambiguity in the choice of Fock representation and associated vacuum. In cosmological backgrounds, the requirement of a unitary implementation of the field dynamics in the physical Hilbert space of the theory is a good criterion to ameliorate such ambiguity. In- deed, this criterion, together with a unitary implementation of the symmetries of the equations of motion, leads to an equivalence class of unitarily equivalent quantizations that, even though it is still formed by an infinite number of Fock representations, is unique. In this work, we apply the procedure developed for fields in cosmological settings to analyze the quantization of a scalar field in the presence of an external electromagnetic classical field in a flat background. We find a natural Fock representation that admits a unitary implementation of the quantum field dynamics. It automatically allows to define a particle number density at all times in the evolution with the correct asymptotic behavior, when the electric field vanishes. Moreover we show the unitary equivalence of all the quantizations that fulfill our criteria, so that they form a unique equivalence class. Although we perform the field quantization in a specific gauge, we also show the equivalence between the procedures taken in different gauges.
Highlights
Critical field, E∗ = m2/e ≈ 1.32 × 1018V/m, called Schwinger limit [14]
We find a natural Fock representation that admits a unitary implementation of the quantum field dynamics
The main result of our study is the proof that all Fock representations that allow for a unitary quantum implementation of the dynamics belong to a unique family of unitarily equivalent quantizations
Summary
We review how the ambiguity in the choice of a complex structure can be related to the freedom of performing canonical transformations in the classical theory. We show how this fact translates, in the quantum theory, to the existence of different possibly inequivalent quantizations, and how imposing unitary implementation of both the symmetries and the evolution can reduce this ambiguity. We discuss the ambiguities due to gauge freedom in the description of the classical background
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