Physical Review Accelerators and Beams (Sep 2021)

Restoring betatron phase coherence in a beam-loaded laser-wakefield accelerator

  • A. Koehler,
  • R. Pausch,
  • M. Bussmann,
  • J. P. Couperus Cabadağ,
  • A. Debus,
  • J. M. Krämer,
  • S. Schöbel,
  • O. Zarini,
  • U. Schramm,
  • A. Irman

DOI
https://doi.org/10.1103/PhysRevAccelBeams.24.091302
Journal volume & issue
Vol. 24, no. 9
p. 091302

Abstract

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Matched beam loading in laser wakefield acceleration, characterizing the state of flattening the accelerating electric field along the bunch, leads to the minimization of energy spread at high-bunch charges. Here, we experimentally demonstrate by independently controlling injected charge and accelerating gradients, using the self-truncated ionization injection scheme, that minimal energy spread coincides with a reduction of the normalized beam divergence. With the simultaneous confirmation of the micrometer-small beam radius at the plasma exit, deduced from betatron radiation spectroscopy, we attribute this effect to the minimization of chromatic betatron decoherence. These findings are supported by rigorous three-dimensional particle-in-cell simulations tracking self-consistently particle trajectories from injection, acceleration until beam extraction to vacuum. We conclude that beam-loaded laser wakefield acceleration enables highest longitudinal and transverse phase space densities.