We offer a unique cryogenic linear quadrupole ion trap with 5 T superconducting solenoid for x-ray magnetic circular dichroism (XMCD) spectroscopy of size-selected cluster ions, molecular ions, and ionic complexes. The radio-frequency ion trap is operated in the space-charge limit for high signal-to-noise ratio. Magnetron sputtering and gas aggregation is the standard ion source, but other ion sources can be added as well.
Because of its complexity, this experimental setup requires thorough consultation with the scientist in charge. Please contact us well ahead of time to discuss experimental feasibility. This is currently the only instrument world-wide that allows performing XMCD studies of cold gas-phase ions.
- metal ion source (single/dual target magnetron sputtering and gas aggregation with additional reactive gas port)
- hexapole collision/reaction cell for preparation of ionic complexes and oxides
- quadrupole mass filter for monodisperse ion beams
- cryogenic ion trap (liquid-helium-cooled) with ion temperatures down to 7.4 K
- buffer gas cooling for Zeeman relaxation
- applied homogeneous magnetic field (0 - 5 T) coaxial with ion trap axis
- reflectron time-of-flight mass spectrometer for partial ion yield detection of x-ray absorption and XMCD spectra
Further ion sources (e.g. electrospray ionization) can be made available upon request.
See here for details of beamline UE52-PGM.
|Temperature range||3 - 300 K|
|Detector||high transmission reflectron time-of-flight mass spectrometer for ion yield spectroscpy|
|Manipulators||cryogenic linear quadrupole ion trap|
|Sample holder compatibility|
|applied magnetic field||0 - 5 T|
|mass range||19.5 mm/440 kHz Extrel quadrupole mass filter: 10 - 4000 amu|
|ion source||magnetron sputtering/gas aggregation ion source (variable; dual target; reactive gas port)|
|sample preparation||hexapole collision cell with reactive gas port|
Nanocluster Trap and its ongoing upgrade program are partially funded by the German Federal Ministry for Education and Research (BMBF) under Grant No. BMBF-05K13VF2.