Activating Cavity by Electrons

TL;DR

This paper explores how free electrons interacting with a cavity containing matter can create metastable states, revealing new ways to control light-matter interactions and electron capture within quantum optical systems.

Contribution

It introduces a novel framework combining electron scattering with quantum light-matter interactions, expanding the understanding of cavity-mediated electron dynamics.

Findings

Electrons can be captured by matter inside a cavity due to cavity effects.

Metastable states form at a wide range of electron energies.

Properties of these states depend on cavity frequency and coupling strength.

Abstract

The interaction of atoms and molecules with quantum light as realized in cavities has become a highly topical and fast growing field of research. This interaction leads to the formation of hybrid light-matter states giving rise to new phenomena and opening up new pathways to control and to manipulate properties of the matter. In this work, we substantially extend the scope of the interaction by allowing free electrons to enter the cavity and merge and unify the two active fields of electron scattering and quantum-light-matter interaction. In the presence of matter, a new kind of metastable states are formed which exist at a large range of electron energies. The properties of these states depend strongly on the frequency and on the light-matter coupling of the cavity. The incoming electrons can be captured by the matter inside the cavity solely due to the presence of the cavity. The findings are substantiated by an explicit example and general striking consequences are discussed.