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X-ray film as a two-dimensional detector for X-ray diffraction analysis

Published online by Cambridge University Press:  06 March 2012

T. N. Blanton
T. N. Blanton*
Affiliation:
Eastman Kodak Company, Imaging Materials and Media Research and Development, Rochester, New York 14650-2106
*
a)Electronic mail: thomas.blanton@kodak.com
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Abstract

Silver halide based photographic imaging elements have been utilized as detectors for X-rays for over 100 years. These elements comprised of gelatin dispersed silver halide coated on one or both sides of a support, have been utilized in diffraction experiments since the discovery of X-ray diffraction by Laue and co-workers. X-ray film has high spatial resolution and can be adapted to flat or curved two-dimensional detection geometries. This paper describes the use of X-ray film as a two-dimensional detector for X-ray diffraction analysis, and discusses X-ray film composition, exposure, and processing, along with considerations for analyzing X-ray diffraction data collected using X-ray film.

Keywords

detectorfilmphotographicX-ray diffraction
Type
Two-Dimensional Detectors
Information
Powder Diffraction , Volume 18 , Issue 2 , June 2003 , pp. 91 - 98
Copyright
Copyright © Cambridge University Press 2005

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References

Blanton, T. N. (1994). “X-ray diffraction orientation studies using two-dimensional detectors,” Adv. X-ray Anal. AXRAAA 37, 367373. axr, AXRAAA Google Scholar
Blanton, T. N., Watkins, T. R., and Howey, M. A. (1997). “The effect of gelatin on silver halide strain in photographic films,” Adv. X-ray Anal. AXRAAA 40, CD-ROM V40_556.PDF. axr, AXRAAA Google Scholar
Carroll, B. H., Higgins, G. C., and James, T. H. (1980). Introduction to Photographic Theory (Wiley-Interscience, New York), 355 pp.Google Scholar
Debye, P.and Scherrer, P. (1916). “Interference in irregularly oriented particles in Röntgen light (in German),” Phys. Z. PHZTAO 17, 227283. phz, PHZTAO Google Scholar
Friedrich, W., Knipping, P., and Laue, M. (1912). “Interference phenomena with Röntgen rays (in German),” Sitzungsber. Kais. Akad. Wiss. Munchen 303–322: Reprinted in Naturwissenschaften NATWAY (1952). 39, 361372. naw, NATWAY Google Scholar
Glasser, O. (1931). Wilhelm Conrad Röntgen and the History of Röntgenrays (in German) (Springer, Berlin), 337 pp.Google Scholar
Haus, A. G., and Cullinan, J. E. (1989). “Screen film processing systems for medical radiography: A historical review,” Radiographics ZZZZZZ 9, 12031224. 6xt, ZZZZZZ Google Scholar
Hull, A. W. (1917). “A new method of X-ray crystal analysis,” Phys. Rev. PHRVAO 10, 661696. phr, PHRVAO Google Scholar
Pizzutiello, R. J., and Cullinan, J. E. (1993). Introduction to Medical Radiographic Imaging (Eastman Kodak Company, Rochester), 237 pp.Google Scholar
Röntgen, W. C. (1895). “On a new kind of rays (in German),” Proceedings of the Würzburg Physico-Medical Society (17 paragraphs written by Röntgen; for a translated version see http://www.emory.edu/X-RAYS/century_05.htm)Google Scholar
Seliger, H. H. (1995). “Wilhelm Conrad Röntgen and the glimmer of light,” Phys. Today PHTOAD 11, 2531. pto, PHTOAD Google Scholar