A new look at the modified Coulomb potential in a strong magnetic field

TL;DR

This paper investigates how a strong magnetic field modifies the Coulomb potential in QED, revealing angle-dependent qualitative changes and confirming results via two different computational methods.

Contribution

It introduces a novel analysis of the Coulomb potential in strong magnetic fields, highlighting angle dependence and potential qualitative changes in the interaction.

Findings

Potential exhibits angle-dependent behavior in strong magnetic fields.

Qualitative change in Coulomb potential occurs at certain angles.

Results from Wilson loop and Born approximation methods coincide.

Abstract

The static Coulomb potential of Quantum Electrodynamics (QED) is calculated in the presence of a strong magnetic field in the lowest Landau level (LLL) approximation using two different methods. First, the vacuum expectation value of the corresponding Wilson loop is calculated perturbatively in two different regimes of dynamical mass $m_{dyn.}$, {\it i.e.}, $|{\mathbf{q}}_{\|}^{2}|\ll m_{dyn.}^{2}\ll |eB|$ and $m_{dyn.}^{2}\ll |\mathbf{q}_{\|}^{2}|\ll|eB|$, where $\mathbf{q}_{\|}$ is the longitudinal components of the momentum relative to the external magnetic field $B$. The result is then compared with the static potential arising from Born approximation. Both results coincide. Although the arising potentials show different behavior in the aforementioned regimes, a novel dependence on the angle $\theta$ between the particle-antiparticle's axis and the direction of the magnetic field is observed. In the regime $|{\mathbf{q}}_{\|}^{2}|\ll m_{dyn.}^{2}\ll |eB|$, for strong enough magnetic field and depending on the angle $\theta$, a qualitative change occurs in the Coulomb-like potential; Whereas for $\theta=0,\pi$ the potential is repulsive, it exhibits a minimum for angles $\theta\in]0,\pi[$.