U. D. Jentschura
Published 2014-01-16Version 1
The purpose of this article is twofold. First, we attempt to give a brief overview of the different application areas of quantum electrodynamics (QED). These include fundamental physics (prediction of atomic energy levels), where the atom may be exposed to additional external fields (hyperfine splitting and g factor). We also mention QED processes in highly intense laser fields, and more applied areas like Casimir and Casimir--Polder interactions. Both the unifying aspects as well as the differences in the the theoretical treatment required by these application areas (such as the treatment of infinities) are highlighted. Second, we discuss an application of the formalism in the fundamentally interesting area of the prediction of energy levels, namely, the hyperfine structure of P states of muonic hydrogen.
Comments: 7 pages; RevTeX; originally published in Can.J.Phys. in 2011; contains a mini-review section on QED
Journal: Can.J.Phys. 89 (2011) 109-115
Non-perturbative evaluation of some QED contributions to the muonic hydrogen $\bm{n=2}$ Lamb shift and hyperfine structure
Measurements of the hyperfine structure of $nP_J$ Rydberg states by microwave spectroscopy in Cs atoms
Measurement of the hyperfine structure of antihydrogen in a beam
![QR code for arXiv:1401.4034 [physics.atom-ph]](http://oss.arxitics.com/images/favicon.svg)