Abstract
We demonstrate that the positive frequency modes for a complex scalar field in a constant electric field (Schwinger modes), in three different gauges, can be represented as exact Lorentzian worldline path integral amplitudes. Although the mathematical forms of the mode functions differ in each gauge, we show that a simple prescription for Lorentzian worldlines' boundary conditions dispenses the Schwinger modes in all three gauges (that we considered) in a unified manner. Following that, using our formalism, we derive the exact Bogoliubov coefficients and, hence, the particle number, \textit{without} appealing to the well-known connection formulas for parabolic cylinder functions. This result is especially relevant in view of the fact that in a general electromagnetic field configuration, one does not have the luxury of closed-form solutions. We argue that the real time worldline path integral approach may be a promising alternative in such non-trivial cases. We also demonstrate, using Picard-Lefschetz theory, how the so-called worldline instantons emerge naturally from relevant saddle points that are complex.
Highlights
The presence of a strong external electromagnetic field destabilizes the vacuum of quantum-field theory (QFT), inducing creation of particle pairs [1,2,3,4]
Several perturbative results of QFT have been verified by impressively stringent tests, obscurities are still abundant in the nonperturbative regime
The Schwinger effect serves as a example for theoretical explorations on the nonperturbative aspects of several fields of physics, ranging from particle physics to cosmology [5,6,7,8,9,10,11,12]
Summary
The presence of a strong external electromagnetic field destabilizes the vacuum of quantum-field theory (QFT), inducing creation of particle pairs [1,2,3,4]. This motivates us to chase the following goal: find a formalism to study pair creation in external backgrounds using both (i) the language most naturally adapted for localized particles, namely, the worldline approach to QFT, and (ii) the signature of spacetime metric that is most natural to the real-world physics, namely, the Lorentzian signature. Towards this objective, in this work, we illustrate how a real-time, worldline path integral formulation can be realized for the simplest case of pair creation in external background, namely, the Schwinger effect in scalar QED. We have delegated the mathematical details of certain results to the Appendixes. [We use the metric signature ð1; −1; −1; −1Þ, .]
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