An Introduction to Renormalization in Atomic Physics

TL;DR

This paper introduces renormalization in atomic physics by analyzing a model of a single electron atom interacting with radiation, focusing on mass renormalization, radiation reaction, and atomic level shifts.

Contribution

It provides a pedagogical framework for renormalization in atomic physics, including mass renormalization and the calculation of atomic level shifts.

Findings

Identification of the radiation reaction force divergence

Derivation of a unique mass renormalization prescription

Calculation of atomic level shifts using renormalized perturbation theory

Abstract

The purpose of these notes is to provide a pedagogical introduction to the concept of renormalization in atomic physics. We study quantum dynamics of a model of a nonrelativistic single electron atom coupled to the quantum radiation field in the dipole approximation. An interaction between the electron and the radiation field is regularized, using a suitable cutoff prescription which eliminates the coupling of the electron to the highly ultraviolet (UV) field modes. Subsequently, we analyze the corresponding Heisenberg picture equations of motion, and focus on behavior of physical observables in the limit of a pointlike electron (i.e., in the limit when the above mentioned UV cutoff is gradually lifted to infinity). We identify the radiation reaction force acting on the electron, and show that this force actually diverges towards infinity when gradually removing the UV cutoff. Such an analysis leads ultimately to an unique renormalization prescription for the electron mass, as well as to determination of the Abraham-Lorentz force acting on the electron. Dependence of the just sketched renormalization procedure upon the spatial dimension is highlighted. Finally, we present an example calculation of the atomic level shifts by means of the renormalized perturbation theory, and formulate also the renormalized mean field theory.