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X-ray Intensities from Copper-Target Diffraction Tubes

Published online by Cambridge University Press:  06 March 2019

M. A. Short
M. A. Short*
Affiliation:
Ford Motor Company, Engineering&Research Staff Dearborn, Michigan. 48121
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Abstract

The relative intensities of the Kα characteristic radiation obtained from copper-target X-ray diffraction tubes have been calculated for a range of tube accelerating voltages and take-off angles. The calculations employ an over-voltage function, and absorption and atomic number corrections similar to those used in electron microprobe analysis. They apply only to constant potential X-ray generators. Measurements of actual intensities obtained on a Picker diffractometer using a sodium chloride monochromator gave relative intensities in close agreement with those calculated. The calculations and measurements show that there is an optimum tube voltage, with respect to intensity, for each take-off angle. This voltage increases with increasing take-off angle. The application of these results to the consideration of the relative intensities obtainable from broad, standard and fine focus copper-target X-ray diffraction tubes is discussed.

Type
X-Ray Instrumentation
Information
Advances in X-Ray Analysis , Volume 20: Twenty-Fifth Annual Conference on Applications of X-ray Analysis, August 4-6, 1976 , 1976 , pp. 565 - 574
Copyright
Copyright © International Centre for Diffraction Data 1976

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References

1. Reed, S. J. B., Electron Microprobe Analysis, Cambridge University Press (1975).Google Scholar
2. Green, M. and Cosslett, V. E., “The Efficiency of Production of Characteristic X-Radiation, in Thick Targets of a Pure Element”, Proc. Phys. Soc. 78, 12061214 (1961).Google Scholar
3. Whiddington, R., “Transmission of Kathode Rays through Matter”, Proc. Roy. Soc. A 86, 360370 (1912).Google Scholar
4. Duncumb, P. and. Reed, S. J. B., “The Calculation of Stopping Power and Backscatter Effects in Electron Probe Microanalysis”, in Heinrich, K. F. J., Editor, Quantitative Electron Probe Microanalysis, pp. 133154, U. S. Department of Commerce, National Bureau of Standards, Special Publication 298 (1968).Google Scholar
5. Bishop, H. E., in Castaing, R., Deschamps, P., & Philibert, J., Editors, Optique des Rayons X et Microanalyse, p. 153, Paris: Hermann (l966); quoted in S. J. B. Reed, Electron Microprobe Analysis, Cambridge University Press (1975).Google Scholar
6. Bethe, H. A., “Zur Theorie des Durchgangs schneller Korpuskularstrahlen durch Materie”, Ann. Phys. Leipz. 5, 325400 (1930).Google Scholar
7. Bethe, H. A. and Ashkin, J., Experimental Nuclear Physics, New York; Wiley (1953); quoted in S. J. B. Reed, Electron Microprobe Analysis, Cambridge University Press (1975).Google Scholar
8. Bloch, F., Zeit. Phys. 81, 363373 (1933); quoted in S. J. B. Reed, Electron Microprobe Analysis, Cambridge University Press (1975).Google Scholar
9. Wilson, R. R., “Range and Ionisation Measurements on High Speed Protons”, Phys. Rev. 60, 749753 (19-41).Google Scholar
10. Livingston, M. S. and Bethe, H. A., “Nuclear Physics Part III” Rev. Mod. Phys. 9, 245390 (1937).Google Scholar
11. Philibert, J., “A Method for Calculating the Absorption Correction in Electron-Prabe Microanalysis”, in Pattee, H. H., Cosslett, V. E., and Engstrom, A., Editors, X-Ray Optics & X-Ray Microanalysis, PP. 379392, New York: Academic Press (1963).Google Scholar
12. Duncumb, P. and Shields, P. K., “Effect of Critical Excitation Potential on the Absorption Correction”, in McKinley, T. D., Heinrich, K. E. J. and Wittry, D. B., Editors, The Electron Microprobe, pp. 284295, New York: John Wiley (1966).Google Scholar
13. Duncumb, P. and Shields, P. K., “Effect of Critical Excitation Potential on the Absorption Correction in X-Ray Microanalysis”, Tube Investments Research Laboratories, Cambridge, Technical Report No. l8l (1964).Google Scholar
14. Heinrich, K. F. J., “Common. Sources of Error in Electron Probe Microanalysis”, In Newkirk, J. B., Mallett, G. B., and Pfeiffer, E. G., Editors, Advances in X-Ray Analysis, vol. 11, pp. 4055, New York: Plenum Press (1968).Google Scholar
15. Parrish, W., “X-Ray Diffraetometry Methods for Complex Powder Patterns”, in van Olphen, H. and Parrish, W., Editors, X-Ray and Electron Methods of Analysis, pp. 135, New York: Plenum Press (1968).Google Scholar