Physical Review X (Feb 2022)

Waveform Control of Relativistic Electron Dynamics in Laser-Plasma Acceleration

  • Julius Huijts,
  • Lucas Rovige,
  • Igor A. Andriyash,
  • Aline Vernier,
  • Marie Ouillé,
  • Jaismeen Kaur,
  • Zhao Cheng,
  • Rodrigo Lopez-Martens,
  • Jérôme Faure

DOI
https://doi.org/10.1103/PhysRevX.12.011036
Journal volume & issue
Vol. 12, no. 1
p. 011036

Abstract

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The interaction of ultraintense laser pulses with an underdense plasma is used in laser-plasma acceleration to create compact sources of ultrashort pulses of relativistic electrons and x rays. The accelerating structure is a plasma wave, or wakefield, that is excited by the laser ponderomotive force, a force that is usually assumed to depend solely on the laser envelope and not on its exact waveform. Here, we use near-single-cycle laser pulses with a controlled carrier-envelope phase to show that the actual waveform of the laser field has a clear impact on the plasma response. The beam pointing of our relativistic electron beam oscillates in phase with the carrier-envelope phase of the laser, at an amplitude of 15 mrad, or 30% of the beam divergence. Numerical simulations explain this observation through asymmetries in the injection and acceleration of the electron beam, which are locked to the carrier-envelope phase. These results imply that we achieve waveform control of relativistic electron dynamics. Our results pave the way to high-precision, subcycle control of electron injection in plasma accelerators, enabling the production of attosecond relativistic electron bunches and x rays.