Compton Scattering of Hermite Gaussian Wave Gamma-Ray

TL;DR

This paper calculates the differential cross sections for Compton scattering of Hermite Gaussian wave gamma-rays, demonstrating how their quantum numbers can be identified through scattering measurements, with potential applications in gamma-ray astronomy.

Contribution

It introduces a method to identify Hermite Gaussian wave gamma-ray quantum numbers via Compton scattering, extending quantum measurement techniques.

Findings

Differential cross sections are symmetric with respect to zx- and zy-planes.

Nodes in the energy spectrum correspond to quantum numbers nx and ny.

The method can be applied to gamma-ray astronomy.

Abstract

We calculate the differential cross sections for Compton scattering of photons described by Hermite Gaussian (HG) wave function in the framework of relativistic quantum mechanics. The HG wave gamma-rays propagating along the z-direction have quantum numbers of nodes of nx and ny in the x- and y-directions, respectively. The calculated differential cross section is symmetric with respect to both the zx- and zy-planes. The nodes whose number is identical with nx and ny appear in the energy spectrum measured in zx- and zy-planes, respectively. These results indicate that it is possible to identify the HG wave photon and its quantum numbers nx and ny by measuring Compton scattering. The present proposed method can be also applied to gamma-ray astronomy.