Multi-GeV Electron Combs from a Plasma Wakefield Accelerator
摘要
Plasma accelerators now produce GeV-class electron beams with brightness and stability sufficient to drive free-electron lasers. Beyond this, they possess a unique yet largely unexplored capability: shaping the phase space of the beam in situ during injection, on femtosecond or shorter timescales. Here we demonstrate this capability by generating a multi-GeV electron comb comprising more than ten microbunches simultaneously separated in both energy and time. Periodic pinching of the drive beam inside its self-excited plasma wake sequentially injects microbunches via ionization of embedded helium atoms at successive betatron oscillations, while the gently varying plasma density maps each bunchlet to a distinct wake phase, compressing electrons trapped over a ~17 cm region into a comb only micrometers long. Individual microbunches exhibit percent-level energy spreads, energy spacing up to ten percent, and contain several picocoulomb charge. The percent-level spreads and parabolic energy-spacing trend provide experimental evidence for sub-femtosecond microbunch durations and few-femtosecond separations as revealed by beam-loading analysis and confirmed by particle-in-cell simulations. This work demonstrates femtosecond, in-situ phase-space shaping in plasma accelerators, paving the way for electron beams with tailored energy-time structure.
引用
@article{arxiv.2607.08069,
title = {Multi-GeV Electron Combs from a Plasma Wakefield Accelerator},
author = {Chaojie Zhang and Douglas Storey and Alexander Knetsch and Brendan D. O'Shea and Robert Ariniello and Sébastien Corde and Thamine N. Dalichaouch and Claudio Emma and Ole G. Finnerud and Spencer Gessner and Claire Hansel and Valentina Lee and Carl A. Lindstrøm and Michael Litos and Nathan Majernik and Kenneth A. Marsh and Warren B. Mori and Mark J. Hogan and Chan Joshi},
journal= {arXiv preprint arXiv:2607.08069},
year = {2026}
}
备注
20 pages, 8 figures