Atoms (Feb 2023)

XUV Fluorescence Detection of Laser-Cooled Stored Relativistic Ions

  • Ken Ueberholz,
  • Lars Bozyk,
  • Michael Bussmann,
  • Noah Eizenhöfer,
  • Volker Hannen,
  • Max Horst,
  • Daniel Kiefer,
  • Nils Kiefer,
  • Sebastian Klammes,
  • Thomas Kühl,
  • Benedikt Langfeld,
  • Markus Loeser,
  • Xinwen Ma,
  • Wilfried Nörtershäuser,
  • Rodolfo Sánchez,
  • Ulrich Schramm,
  • Mathias Siebold,
  • Peter Spiller,
  • Markus Steck,
  • Thomas Stöhlker,
  • Thomas Walther,
  • Hanbing Wang,
  • Christian Weinheimer,
  • Weiqiang Wen,
  • Danyal Winters

DOI
https://doi.org/10.3390/atoms11020039
Journal volume & issue
Vol. 11, no. 2
p. 39

Abstract

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An improved moveable in vacuo XUV fluorescence detection system was employed for the laser cooling of bunched relativistic (β = 0.47) carbon ions at the Experimental Storage Ring (ESR) of GSI Helmholtzzentrum Darmstadt, Germany. Strongly Doppler boosted XUV fluorescence (∼90 nm) was emitted from the ions in a forward light cone after laser excitation of the 2s–2p transition (∼155 nm) by a new tunable pulsed UV laser system (257 nm). It was shown that the detected fluorescence strongly depends on the position of the detector around the bunched ion beam and on the delay (∼ns) between the ion bunches and the laser pulses. In addition, the fluorescence information could be directly combined with the revolution frequencies of the ions (and their longitudinal momentum spread), which were recorded using the Schottky resonator at the ESR. These fluorescence detection features are required for future laser cooling experiments at highly relativistic energies (up to γ∼ 13) and high intensities (up to 1011 particles) of ion beams in the new heavy ion synchrotron SIS100 at FAIR.

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