Coincidence detection probability of $(\gamma, 2e)$ photoemission measurement

TL;DR

This paper analyzes the coincidence detection probability in $( ext{γ}, 2e)$ photoemission measurements, revealing its relation to two-body correlations and its potential to study center-of-mass physics of electron pairs in condensed matter.

Contribution

It clarifies how the $( ext{γ}, 2e)$ technique relates to the two-body Bethe-Salpeter wave function and identifies its capability to resolve center-of-mass properties of electron pairs.

Findings

Coincidence detection probability relates to the two-body Bethe-Salpeter wave function.

Electron-electron interactions affect the ability to reveal inner-pair structures.

The technique can resolve the center-of-mass momentum and energy of electron pairs.

Abstract

In the study of strongly correlated electrons, one of the challenging core tasks is to develop the potential techniques for direct detection of the many-body correlations of strongly correlated electrons. The $(\gamma, 2e)$ photoemission technique has been developed to investigate the two-body correlations of the target correlated electrons. In this article, we will focus on this technique for the correlated electrons near the Fermi energy in condensed matter. The coincidence detection probability of the two emitted electrons in the $(\gamma, 2e)$ photoemission measurement is shown to be relevant to a two-body Bethe-Salpeter wave function, which describes the dynamical two-body correlations of the target correlated electrons near the Fermi energy. As the coincidence detection probability involves an electron-electron interaction matrix element, the arbitrary momentum and/or energy transfer due to this electron-electron interaction makes the $(\gamma, 2e)$ photoemission technique fail to reveal the inner-pair structures of the two-body Bethe-Salpeter wave function. However, the center-of-mass momentum and energy of the two-body Bethe-Salpeter wave function can be distinctly resolved. Thus, the $(\gamma, 2e)$ photoemission technique can provide the center-of-mass physics of the two-body correlations of the target correlated electrons. It will be one potential technique to study the center-of-mass physics of the Cooper pairs in superconductor.