Causality in quantum field theory with classical sources
Review article, 2019

In an exact quantum-mechanical framework we show that space-time expectation values of the second-quantized electromagnetic fields in the Coulomb gauge in the presence of a classical conserved source automatically lead to causal and properly retarded h-independent electromagnetic field strengths. The classical h-independent and gauge invariant Maxwell's equations naturally emerge in terms of quantum-mechanical expectation values and are therefore also consistent with the classical special theory of relativity. The fundamental difference between interference phenomena due to the linear nature of the classical Maxwell theory as considered in, e.g., classical optics, and interference effects of quantum states is clarified. In addition to these issues, the framework outlined also provides for a simple approach to invariance under time-reversal, some spontaneous photon emission and/or absorption processes as well as an approach to Vavilov-Cherenkov radiation. The inherent and necessary quantum uncertainty, limiting a precise space-time knowledge of expectation values of the quantum fields considered, is, finally, recalled.

quantum uncertainty

retardation

gauge invariance

radiation processes

causality

classical and quantum intereference

quantum field theory

Author

Bo-Sture K. Skagerstam

Norwegian University of Science and Technology (NTNU)

Karl-Erik Eriksson

Chalmers, Space, Earth and Environment, Physical Resource Theory

Per K. Rekdal

Molde University College

JOURNAL OF PHYSICS COMMUNICATIONS

2399-6528 (ISSN)

Vol. 3 8 UNSP 082001

Subject Categories

Atom and Molecular Physics and Optics

Other Physics Topics

Mathematical Analysis

DOI

10.1088/2399-6528/ab3c1c

More information

Latest update

10/10/2019