Physical Review Research (Oct 2023)

Experimental investigation of the interplay between optical and plasma smoothing induced on a laser megajoule beamline

  • S. Depierreux,
  • D. Pesme,
  • R. Wrobel,
  • D. T. Michel,
  • P.-E. Masson-Laborde,
  • G. Riazuelo,
  • E. Alozy,
  • N. Borisenko,
  • A. Orekhov,
  • M. Casanova,
  • A. Casner,
  • M. Grech,
  • A. Heron,
  • S. Huller,
  • P. Loiseau,
  • C. Meyer,
  • P. Nicolaï,
  • C. Riconda,
  • V. Tikhonchuk,
  • C. Labaune

DOI
https://doi.org/10.1103/PhysRevResearch.5.043060
Journal volume & issue
Vol. 5, no. 4
p. 043060

Abstract

Read online Read online

Past experiments [S. Depierreux et al., Phys. Rev. Lett. 102, 195005 (2009)10.1103/PhysRevLett.102.195005] have exhibited the plasma-induced incoherence (PII) process and the reduced imprint in the multikilojoule regime when a thin low-density foam is disposed in front of a solid target. Complementary experiments have been designed to analyze the mechanisms involved, the important parameters, and the role of the optical smoothing in the case of the laser megajoule. Forward stimulated Brillouin scattering (FSBS) is identified as the dominant mechanism governing the angular spray of the laser. FSBS also increases the laser bandwidth and imparts levels of temporal and spatial incoherencies beyond the present capacities of the optical smoothing of the megajoule laser facilities. Such a PII beam becomes suitable to achieve the high degree of irradiation uniformity required to experiment high-convergence efficient direct-drive inertial confinement fusion configurations at the megajoule scale which would otherwise require major changes in the laser chains. By reducing backscattering losses and/or allowing less optically applied smoothing, PII could relax the constraints imposed on the laser system and open the road to an increase in the energy coupled to the target in indirect-drive experiments.