Vacuum Polarization and Photon Propagation in an Electromagnetic Plane Wave

TL;DR

This paper develops a perturbative approach to analyze vacuum polarization and photon propagation in spatially and temporally varying electromagnetic plane waves, revealing how field variations influence refractive indices without limitations on field strength or photon energy.

Contribution

It introduces a combined perturbation and gradient expansion method to calculate vacuum polarization effects in dynamic electromagnetic fields, extending previous static or limited-energy analyses.

Findings

Refractive index can be less than unity in strong fields.

Field variations mainly affect the imaginary part of the refractive index.

No restrictions on field strength or photon energy in the analysis.

Abstract

The QED vacuum polarization in external monochromatic plane-wave electromagnetic fields is calculated with spatial and temporal variations of the external fields being taken into account. We develop a perturbation theory to calculate the induced electromagnetic current that appears in the Maxwell equations, based on Schwinger's proper-time method, and combine it with the so-called gradient expansion to handle the variation of external fields perturbatively. The crossed field, i.e., the long wavelength limit of the electromagnetic wave is first considered. The eigenmodes and the refractive indices as the eigenvalues associated with the eigenmodes are computed numerically for the probe photon propagating in some particular directions. In so doing, no limitation is imposed on the field strength and the photon energy unlike previous studies. It is shown that the real part of the refractive index becomes less than unity for strong fields, the phenomenon that has been known to occur for high-energy probe photons. We then evaluate numerically the lowest-order corrections to the crossed-field resulting from the field variations in space and time. It is demonstrated that the corrections occur mainly in the imaginary part of the refractive index.