Mikael Otendal scite author profile

We demonstrate an anode concept, based on a liquid-metal jet, for improved brightness in compact electron-impact x-ray sources. The source is demonstrated in a proof-of-principle experiment where a 50 keV, ϳ100 W electron beam is focused on a 75 m liquid-solder jet. The generated x-ray flux and brightness is quantitatively measured in the 7-50 keV spectral region and found to agree with theory. Compared to rotating-anode sources, whose brightness is limited by intrinsic thermal properties, the liquid-jet anode could potentially be scaled to achieve a brightness Ͼ100ϫ higher than current state-of-the-art sources. Applications such as mammography, angiography, and diffraction would benefit from such a compact high-brightness source.

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A 9keV electron-impact liquid-gallium-jet x-ray source

Otendal

Tuohimaa

Vogt

et al. 2008

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We demonstrate a high-brightness compact 9 keV electron-impact microfocus x-ray source based on a liquid-gallium-jet anode. A approximately 30 W, 50 kV electron gun is focused onto the approximately 20 ms, 30 mum diameter liquid-gallium-jet anode to produce an approximately 10 microm full width at half maximum x-ray spot. The peak spectral brightness is >2 x 10(10) photons(s mm(2) mrad(2)x0.1% BW). Calculation and experiments show potential for increasing this brightness by approximately three orders of magnitude, making the source suitable for laboratory-scale x-ray crystallography and hard x-ray microscopy.

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Phase-contrast x-ray imaging with a liquid-metal-jet-anode microfocus source

Tuohimaa¹,

Otendal²,

Hertz³

2007

Appl. Phys. Lett.

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Liquid-tin-jet laser-plasma extreme ultraviolet generation

Jansson¹,

Hansson²,

Hemberg³

et al. 2004

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Liquid-metal-jet anode x-ray tube

2004

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We describe a novel electron-impact x-ray source based on a high-speed liquid-metal-jet anode. Thermal power load calculations indicate that this new anode concept potentially could increase the achievable brightness in compact electron-impact x-ray sources by more than a factor 100 compared to current state-of-the-art rotating-anode or microfocus sources. A first, successful, low-power proof-of-principle experiment is described and the feasibility of scaling to high-brightness and high-power operation is discussed. Some possible applications that would benefit from such an increase in brightness are also briefly described.

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Mikael Otendal

Liquid-metal-jet anode electron-impact x-ray source

A 9keV electron-impact liquid-gallium-jet x-ray source

Phase-contrast x-ray imaging with a liquid-metal-jet-anode microfocus source

Liquid-tin-jet laser-plasma extreme ultraviolet generation

Liquid-metal-jet anode x-ray tube

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