Quantum free-electron laser oscillator

TL;DR

This paper proposes a quantum free-electron laser oscillator that enhances quantum effects in radiation, reduces intensity fluctuations, and could improve imaging and interferometry by demonstrating quantum photon statistics.

Contribution

It introduces a novel quantum free-electron laser oscillator scheme that achieves near-coherent photon statistics and sub-Poissonian light, addressing experimental challenges of single-pass quantum FELs.

Findings

Photon statistics closer to a coherent state

Potential for sub-Poissonian photon statistics

Reduced intensity fluctuations in emitted radiation

Abstract

If the quantum mechanical recoil of the electron due to its scattering from the undulator and laser fields dominates the dynamics, a regime of the free-electron laser emerges where quantum effects lead to a drastic change in the radiation properties. However, the large interaction length required for a single-pass quantum free-electron laser impedes the experimental realization. The quantum free-electron laser oscillator, proposed in the present article, is a possible scheme to resolve this issue. Here we show that this device features a photon statistics that is closer to a coherent state in comparison to existing classical free-electron lasers. The device can be even operated in such a way that a sub-Poissonian statistics is obtained. Beside the benefit of demonstrating this pure quantum effect, the narrowing of the photon distribution implies reduced intensity fluctuations of the emitted radiation, which in turn lead to decreased noise in imaging experiments or to an enhanced sensitivity in interferometric applications.