Physical Review Accelerators and Beams (Sep 2019)

Low power commissioning of an innovative laser beam circulator for inverse Compton scattering γ-ray source

  • Cheikh Fall Ndiaye,
  • Kevin Cassou,
  • Patrick Cornebise,
  • Kevin Dupraz,
  • Denis Douillet,
  • Titouan Le Barillec,
  • Christopher Magueur,
  • Aurélien Martens,
  • Daniele Nutarelli,
  • Yann Peinaud,
  • Alice Thiébault,
  • Themistoklis Williams,
  • Fabian Zomer,
  • Nicolas Beaugérard,
  • Bastien Lacrampe,
  • Hervé Rocipon,
  • David Alesini,
  • Fabio Cardelli,
  • Antonio Falone,
  • Giovanni Franzini,
  • Alessandro Gallo,
  • Simona Incremona,
  • Luca Piersanti,
  • Valerio Petinacci,
  • Stefano Pioli,
  • Alessandro Variola,
  • Andrea Mostacci,
  • L. Serafini,

DOI
https://doi.org/10.1103/PhysRevAccelBeams.22.093501
Journal volume & issue
Vol. 22, no. 9
p. 093501

Abstract

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We report on the optical commissioning of the high power laser beam circulator for the high brightness Compton γ-ray source Extreme Light Infrastructure for Nuclear Physics. Tests aiming at demonstrating the optical performances of the laser beam circulator have been realized with a low-power pulsed laser-beam system and without electron beam. We show that, with the developed alignment and synchronization methods coming from the laser beam circulator design study presented in the Dupraz et al. paper [Phys. Rev. Accel. Beams 17, 033501 (2014)], the laser beam circulator enhances the laser-beam power available at the interaction point by a factor in excess of 25. This corresponds to a potential of bringing the average laser-beam power in excess of 1 kW when the laser beam circulator is injected with the interaction point laser-beam pulse energy of 400 mJ at 100 Hz.