Physical Review X (Aug 2017)

Extreme-Ultraviolet Vortices from a Free-Electron Laser

  • Primož Rebernik Ribič,
  • Benedikt Rösner,
  • David Gauthier,
  • Enrico Allaria,
  • Florian Döring,
  • Laura Foglia,
  • Luca Giannessi,
  • Nicola Mahne,
  • Michele Manfredda,
  • Claudio Masciovecchio,
  • Riccardo Mincigrucci,
  • Najmeh Mirian,
  • Emiliano Principi,
  • Eléonore Roussel,
  • Alberto Simoncig,
  • Simone Spampinati,
  • Christian David,
  • Giovanni De Ninno

DOI
https://doi.org/10.1103/PhysRevX.7.031036
Journal volume & issue
Vol. 7, no. 3
p. 031036

Abstract

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Extreme-ultraviolet vortices may be exploited to steer the magnetic properties of nanoparticles, increase the resolution in microscopy, and gain insight into local symmetry and chirality of a material; they might even be used to increase the bandwidth in long-distance space communications. However, in contrast to the generation of vortex beams in the infrared and visible spectral regions, production of intense, extreme-ultraviolet and x-ray optical vortices still remains a challenge. Here, we present an in-situ and an ex-situ technique for generating intense, femtosecond, coherent optical vortices at a free-electron laser in the extreme ultraviolet. The first method takes advantage of nonlinear harmonic generation in a helical undulator, producing vortex beams at the second harmonic without the need for additional optical elements, while the latter one relies on the use of a spiral zone plate to generate a focused, micron-size optical vortex with a peak intensity approaching 10^{14} W/cm^{2}, paving the way to nonlinear optical experiments with vortex beams at short wavelengths.