Auger photoemission as a laser-like coherent cathode

TL;DR

This paper proposes a novel Auger photoemission mechanism to generate a coherent, bright electron source, potentially advancing quantum technologies and overcoming limitations of current cathodes.

Contribution

It introduces a photon-induced four-level Auger process for collective electron emission, combining photoemission and Auger recombination to produce coherent electron beams.

Findings

Identifies conditions for coherent Auger photoemission, including population inversion.

Highlights potential for nanofabrication of Auger photocathodes.

Provides insights for experimental realization of coherent electron sources.

Abstract

In pursuit of quantum advancements across disciplines, a bright and coherent electron source is expected to be a cornerstone of diverse applications including electron microscopy, laser accelerators, and free electron lasers. Current cathodes, such as cold field and photoemission, can generate high-quality electron beams with different cathode materials, geometric configurations, and laser excitation profiles, but their maintenance of both quantum coherence and high beam brightness suffers from the space-charge repulsion of many electrons. Here, we propose a new mechanism to provide collective emission of coherent electrons based on Auger photoemission. Our approach leverages a photon-induced four-level Auger process that necessitates a combination of photoemission and Auger recombination. The Auger electrons, energized through a recycling process of photoelectrons, emit collectively into the vacuum as secondary electrons. We compare coherent and incoherent Auger photoemission, identifying that the working condition of the coherent photoemission requires population inversion, akin to the four-level laser system. Our work provides insights for experimental realization and nanofabrication of Auger photocathodes, addressing a critical need in advancing quantum technologies relating to correlated coherent sources.