Applied Sciences (Feb 2018)

Radiation Pressure-Driven Plasma Surface Dynamics in Ultra-Intense Laser Pulse Interactions with Ultra-Thin Foils

  • Bruno Gonzalez-Izquierdo,
  • Remi Capdessus,
  • Martin King,
  • Ross J. Gray,
  • Robbie Wilson,
  • Rachel J. Dance,
  • John McCreadie,
  • Nicholas M. H. Butler,
  • Steve J. Hawkes,
  • James S. Green,
  • Nicola Booth,
  • Marco Borghesi,
  • David Neely,
  • Paul McKenna

DOI
https://doi.org/10.3390/app8030336
Journal volume & issue
Vol. 8, no. 3
p. 336

Abstract

Read online

The dynamics of the plasma critical density surface in an ultra-thin foil target irradiated by an ultra-intense (∼6 × 10 20 Wcm − 2 ) laser pulse is investigated experimentally and via 2D particle-in-cell simulations. Changes to the surface motion are diagnosed as a function of foil thickness. The experimental and numerical results are compared with hole-boring and light-sail models of radiation pressure acceleration, to identify the foil thickness range for which each model accounts for the measured surface motion. Both the experimental and numerical results show that the onset of relativistic self-induced transparency, in the thinnest targets investigated, limits the velocity of the critical surface, and thus the effectiveness of radiation pressure acceleration.

Keywords