Undulator Radiation from a Single Electron: A Temporal Double-Slit Experiment

TL;DR

This paper demonstrates that a single relativistic electron can produce an interference pattern in its emitted synchrotron radiation spectrum, revealing quantum coherence effects in the time domain through a double-slit experiment analogy.

Contribution

It presents the first low-intensity double-slit experiment in the time domain with a single electron, showing coherent photon emission over meters and spectral interference patterns.

Findings

Single-electron synchrotron radiation exhibits interference fringes.

Spectral distribution from a single electron matches that from many electrons.

Coherent photon emission is delocalized over several meters.

Abstract

Double-slit diffraction studies with photons or massive particles rank among the most beautiful experiments in physics. In particular, measurements at very low intensities demonstrate the particle-wave duality and the coherent superposition of states very clearly. In this paper, low-intensity double-slit experiments in the time domain are presented measuring the spectral distribution of synchrotron light from a single relativistic electron in a storage ring. In two consecutive radiation sources (so-called undulators) with a magnetic detour between them, electrons emit two temporally separated light pulses leading to a spectrum with interference fringes, very much like the angular distribution of light behind two spatially separated slits. Independent experiments at two synchrotron light sources (DELTA in Germany and UVSOR-III in Japan) directly demonstrate that the spectral distribution of accumulated synchrotron light from a single electron is essentially the same as the spectrum from a beam of many electrons. While the latter is usually explained as interference between electromagnetic waves from the two undulators, the single-electron experiments demonstrate that coherent photon emission is delocalized over several meters and the accumulated spectral distribution exhibits a deterministic interference pattern at small wavelengths. The experiments presented here were conducted with near-ultraviolet light to avoid an elaborate in-vacuum setup, but the very wide spectral range of synchrotron radiation, from infrared light to X-rays, enables access to regimes not available in laser-based quantum optics experiments.