Quasi-static Limits in Nonrelativistic Quantum Electrodynamics

TL;DR

This paper investigates the nonrelativistic limit of quantum electrodynamics for particles with small velocities, deriving effective particle dynamics, including Coulomb and Darwin interactions, and analyzing radiation effects.

Contribution

It constructs invariant subspaces and describes effective dynamics for particles in the quasi-static limit without infrared cutoff, including electromagnetic corrections and radiation analysis.

Findings

Effective particle dynamics include Coulomb and Darwin interactions.

Constructed invariant subspaces up to order epsilon sqrt{log(epsilon^{-1})}.

Calculated radiated energy and wave function leakage.

Abstract

We consider a system of N nonrelativistic particles of spin 1/2 interacting with the quantized Maxwell field (mass zero and spin one) in the limit when the particles have a small velocity, imposing to the interaction an ultraviolet cutoff, but no infrared cutoff. Two ways to implement the limit are considered: c going to infinity with the velocity v of the particles fixed, the case for which rigorous results have already been discussed in the literature, and v going to 0 with c fixed. The second case can be rephrased as the limit of heavy particles, m_{j} --> epsilon^{-2}m_{j}, observed over a long time, t --> epsilon^{-1}t, epsilon --> 0^{+}, with kinetic energy E_{kin} = Or(1). Focusing on the second approach we construct subspaces which are invariant for the dynamics up to terms of order epsilon sqrt{log(epsilon^{-1})} and describe effective dynamics, for the particles only, inside them. At the lowest order the particles interact through Coulomb potentials. At the second one, epsilon^{2}, the mass gets a correction of electromagnetic origin and a velocity dependent interaction, the Darwin term, appears. Moreover, we calculate the radiated piece of the wave function, i. e., the piece which leaks out of the almost invariant subspaces and calculate the corresponding radiated energy.