We present a laser driven soft x-ray source based on a novel solid argon filament. The continuously flowing micron-sized filament (diameter 56μm, flow speed 5mms) was used as a laser target in order to generate a plasma source of high brightness in the “water window” (2.24.4nm) spectral range. The emission properties of the source were characterized in detail with respect to crucial parameters such as positional and energy stability using an extreme ultraviolet (XUV) sensitive pinhole camera and an XUV spectrometer. The results are compared with an argon plasma based on a gas puff target operated under the same experimental conditions showing an increase of the brilliance by a factor of 84. By changing the capillary geometry from a constant diameter to a convergent shape the flow speed of the filament was significantly increased up to 250mms, facilitating the operation at higher repetition rates.

Topics
Back pressure, Vacuum apparatus, Cameras, Laser-induced plasma, Chemical elements, Emission spectroscopy, Gas jet, Band emission, X-ray absorption spectroscopy, Plasma sources
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© 2007 American Institute of Physics.
2007
American Institute of Physics
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