Physical Review Research (Jul 2024)

Ultrabroad-band x-ray source using a picosecond, laser-driven plasma accelerator

  • N. Lemos,
  • P. M. King,
  • D. Rusby,
  • I. Pagano,
  • M. Sinclair,
  • K. A. Marsh,
  • J. L. Shaw,
  • A. L. Milder,
  • A. Pak,
  • B. B. Pollock,
  • M. Aufderheide,
  • F. V. Hartemann,
  • S. Q. Wu,
  • Y. Hwang,
  • B. M. Hegelich,
  • J. Moody,
  • P. Michel,
  • C. Joshi,
  • F. Albert

DOI
https://doi.org/10.1103/PhysRevResearch.6.L032022
Journal volume & issue
Vol. 6, no. 3
p. L032022

Abstract

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An ultrabroad-band x-ray source, with photon energies from 10 keV to >1 MeV, based on a picosecond laser-driven plasma accelerator, is characterized and used to radiograph high-energy-density-science relevant targets. The measured yield of 10^{12} photons/shot is reaching the necessary photon yields to radiograph, in a single shot, high areal density objects and matter under extreme conditions. By focusing a short laser pulse (120 J, 1 ps) into a gas jet, a <100 mrad electron beam with energies up to 350 MeV and up to 70 nC of charge was produced by a combination of laser self-modulation instability and direct laser acceleration. A foil placed at the exit of the gas jet is used to convert part of the electron beam energy into x rays through inverse bremsstrahlung and/or inverse Compton scattering, generating a bright, broad-band, high-photon-energy beam. This beam is used to radiograph a gold half hohlraum with a high-density sphere inside with relevant characteristics for high-energy-density science and inertial confinement fusion.