Physical Review Research (Aug 2022)

Transition to efficient, unsuppressed bulk-target ion acceleration via high-fluence laser irradiation

  • D. P. Higginson,
  • J. Kim,
  • G. M. Petrov,
  • D. C. Swift,
  • J. A. Cobble,
  • D. L. Bleuel,
  • J. A. Frenje,
  • V. Yu. Glebov,
  • C. Stoeckl,
  • J. M. McNaney,
  • F. N. Beg

DOI
https://doi.org/10.1103/PhysRevResearch.4.033113
Journal volume & issue
Vol. 4, no. 3
p. 033113

Abstract

Read online Read online

A high-intensity laser irradiating a few-μm solid foil will accelerate ions from the bulk of the target as well as protons from a surface contaminant layer. Experimental measurements of ion spectra using the OMEGA EP laser (0.25–1 kJ, 10 ps) show, as suggested previously [Petrov et al., Phys. Plasmas 17, 103111 (2010)1070-664X10.1063/1.3497002], that at a laser fluence exceeding 1 J/μm^{2}, the contaminant layer is accelerated enough that ions from the bulk of the target are more effectively accelerated. When using CD_{2} as a target, the high fluence results in a 100-fold increase in deuteron acceleration efficiency (near 1% of laser energy) compared to subthreshold fluence. This is found to be due to the fact that the deuterons have a higher density at many locations during acceleration, allowing a larger electric field to develop, leading to improved efficiency. Using a pitcher-catcher setup, these deuterons, as well as protons from the contaminant layer, strike a LiF target and generate neutrons via (d,n) and (p,n) nuclear reactions. CR39 plastic and nuclear activation detectors measured broadband neutron yields of 4×10^{9}sr^{−1} and yields of 10^{8}sr^{−1} for neutrons above 11 MeV.