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X-ray sources

X-ray sources. Sealed tubes - Coolidge type common - Cu, Mo, Fe, Cr, W, Ag intensity limited by cooling req'ments (2-2.5kW). X-ray sources. Sealed tubes - Coolidge type common - Cu, Mo, Fe, Cr, W, Ag intensity limited by cooling req'ments (2-2.5kW)

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X-ray sources

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  1. X-ray sources Sealed tubes - Coolidge type common - Cu, Mo, Fe, Cr, W, Ag intensity limited by cooling req'ments (2-2.5kW)

  2. X-ray sources Sealed tubes - Coolidge type common - Cu, Mo, Fe, Cr, W, Ag intensity limited by cooling req'ments (2-2.5kW) Intensity also changes w/ take-off angle

  3. X-ray sources Intensity also changes w/ take-off angle But resolution decreases w/ take-off angle

  4. X-ray sources

  5. X-ray sources Rotating anode high power - 40 kW demountable various anode types

  6. X-ray sources Synchrotron need electron or positron beam orbiting in a ring beam is bent by magnetic field x-ray emission at bend

  7. X-ray sources Synchrotron need electron or positron beam orbiting in a ring beam is bent by magnetic field x-ray emission at bend Advantages 10-4 - 10-5 rad divergence (3-5 mm @ 4 m)

  8. X-ray sources Synchrotron need electron or positron beam orbiting in a ring beam is bent by magnetic field x-ray emission at bend Advantages 10-4 - 10-5 rad divergence (3-5 mm @ 4 m) high brilliance wavelength tunable

  9. X-ray sources Synchrotron Advantages 10-4 - 10-5 rad divergence (3-5 mm @ 4 m) high brilliance wavelength tunable

  10. X-ray sources Synchrotron Advantages 10-4 - 10-5 rad divergence (3-5 mm @ 4 m) high brilliance wavelength tunable

  11. X-ray sources Synchrotron Advantages 10-4 - 10-5 rad divergence (3-5 mm @ 4 m) high brilliance wavelength tunable

  12. X-ray sources Synchrotron need electron or positron beam orbiting in a ring beam is bent by magnetic field x-ray emission at bend Advantages 10-4 - 10-5 rad divergence (3-5 mm @ 4 m) high brilliance wavelength tunable high signal/noise ratio

  13. Beam conditioning Collimation

  14. Beam conditioning Monochromatization -filters – matls have at. nos. 1 or 2 less than anode 50-60% beam attenuation placing after specimen/before detector suppresses sample fluorescence allows passage of high intensity & long wavelength white rad.

  15. Beam conditioning Monochromatization -filters – matls have at. nos. 1 or 2 less than anode 50-60% beam attenuation placing after specimen/before detector suppresses sample fluorescence allows passage of high intensity & long wavelength white rad.

  16. Beam conditioning Monochromatization Crystal monochromators – LiF, SiO2, pyrolytic graphite critical – reflectivity ex: for MoK, LiF 9.4% graphite 54 %

  17. Beam conditioning Monochromatization Crystal monochromators – LiF, SiO2, pyrolytic graphite critical – reflectivity ex: for MoK, LiF 9.4% graphite 54 % resolution – determines peak/bkgrd ratio & spectral purity best - Si – 10" graphite – 0.52°

  18. Beam conditioning Monochromatization Monochromator shape usually flat – problems w/ divergent beams concentrating type – increases I by factor of 1.5-2

  19. Beam conditioning Monochromatization Monochromator shape focusing monochromators elastically or plastically bend crystal

  20. Beam conditioning Monochromatization Monochromator shape focusing monochromators elastically or plastically bend crystal Johann geometry radius of curvature = 2R R = radius of instrument focusing circle

  21. Beam conditioning Monochromatization Monochromator shape focusing monochromators elastically or plastically bend crystal Johansson geometry bend radius = 2R ground radius = R

  22. Beam conditioning • Mirrors • total reflection below critical angle • polished Al or optical glass • curved mirrors collimate, can even focus beam • (high peak to bkgrd ratio)

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