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Measuring Techniques of Parallel Beam-Diffraction Micrography

Published online by Cambridge University Press:  06 March 2019

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Abstract

Examination of the substructure of crystalline solids by diffractographic methods has recently developed into an independent field of work alongside atomicstructure analysis. Diffraction micrography with electrons is characterized by the small size of the distortion fields and the high resolving power in small crystal ranges (1000-3000Å thickness). X-ray diffraction micrography is characterized by great reciprocation between wave field and distortion field and by undisturbed preparation and undisturbed testing in the large crystal ranges (up to 15 cm2). There are two groups of examination methods for diffraction micrography with X-rays: (1) Examination with a finely limited, polychromatic or monochromatic X-ray source and moving sample, according to A. R. Lang et al. (2) Examination with a parallel-ray beam of polychromatic or monochromatic X-rays with fixed sample, in accordance with Berg-Barrett et al. For the examination of coarse defects in single-crystalline and poly crystalline matter, the parallel-beam method offers a wide scope for studies in the physics and applications of single-crystal line and polycrystalline solids. This paper therefore includes a summary of the methods using collimation systems and grating diaphragms. Measuring techniques and results are illustrated with the help of reflection and transmission pictures on various crystals. The various methods and refined measuring technique of the parallel-beam method enable the following to be defined: (1) Localization of crystallites from 20 μ diam. upward in a surface up to 15 cm2. (2) Determination of the faces of averted crystallites from 20 µ diam. upward in crystal surfaces. (3) Angle of avertence of crystallites or curvature angles of net faces from 1 to 3° in crystal surfaces up to 15 cm2. (4) Subangle grain boundaries, slip bands, and dislocation lines; also distortion fields (from 20 μ upward) resulting from mechanical, thermal, and radiation damage.

Type
Research Article
Copyright
Copyright © International Centre for Diffraction Data 1966

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References

1. Berg, W., “Über eine rontgenographische Méthode zur Untersuchung von Gitterstorungen an Kristallen,” Naturwiss. 19: 391, 1931.Google Scholar
2. Berg, W., “About the History of Load aod Deformed Crystals,” Z. Krist, 89: 286, 1934.Google Scholar
3. Barrett, C. S., Trans. AIME 161: 15, 1945.Google Scholar
4. Guiflier, A. and Tennevin, J., “Sur Deux Variantes de la Méthode de Laue et Leurs Applications,” Acta Cryst. 2: 133, 1949.Google Scholar
5. Barth, H., “Monochromatisierung einer Röntgen-Spektrallinie,” Z. Naturforsch. 13a: 680, 1958.Google Scholar
6. Barth, H., “Analyse der Realstruktur von Einkiistallen,” Z. Elecktrochem. 63: 908, 1959.Google Scholar
7. Earth, H., “Gefugeanalyse vonEinkristallenmit der Parallelstrahlmethode,” Fortschr, Minerai 38: 53, 1960.Google Scholar
8. Wadewite, H., “ZUT Bestimmung der Subkornwinkelmittels Berg-Barrett-Technik,” Manuscript, 1963.Google Scholar
9. Bond, W. L. and Andrus, J., “Structural Imperfections in Quarts Crystals,” Am-Minertdogist 37: 622632, 1952.Google Scholar
10. Bonse, U., “Zur röntgenographischen Bestimmung des Typs einzelner Versetzungen in Einkristallen,” Z. Physik 153: 278, 1958.Google Scholar
11. Newkirk, J. B., “Method for the Detection of Dislocations in Silicon by X-ray Extinction Contrast,” Phys, Rev. 110: 1465, 1958.Google Scholar
12. Lang, A. R., “Direct Observation of Individual Dislocations by X-.Ray Diffraction,” J. Appl. Phys. 29: 597, 1958.Google Scholar
13. Barth, H. und Hosemann, R., “Anwendung der Parallelstrahlmethode im Durchstrahlungsfall zur Prüfung des Kristallinneren mit Rontgen-Strahlen,” Z. Naturforsch, 13a: 792, 1958.Google Scholar
14. Lang, A. R., “The Projection Topograpfi: A New Method in X-Ray Diffraction Microradiography,” Acta Cryst. 12: 249, 1959.Google Scholar
15. Geroldund, V. Meier, F., “Der röntgenographische Nachweis von Versetzungen in Germanium,” Z. Phys. 155: 387394, 1959.Google Scholar
16. Renninger, M., “Eingefrorene und reversible Gitteryerzerrungen,” Phys. Letters 1: 106, 1962.Google Scholar
17. Renninger, M., “Netzebenen-Interferonetrie,” Phys. Letters 1: 104, 1962.Google Scholar