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The Ladell Diffractometer: Geometry and Applications

Published online by Cambridge University Press:  06 March 2019

Berton Greenberg
Berton Greenberg*
Affiliation:
Philips Laboratories, 345 Scarborough Road, Briarcliff Manor, New York 10510
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Abstract

The Ladell x-ray diffractometer (LD) is designed to study “practical” polycrystalline materials. These are materials which exhibit some combination of texture, strain, and large grain size, or are inhomogeneous or anisotropic in other ways. LD features which make this possible are: the ability to study crystal planes inclined to the sample surface; a versatile reflection geometry; high 2θ resolution via a focusing geometry; a large irradiated sample area (up to 1.5 cm2) for improved intensity and sampling statistics; the ability to examine different sample areas to test for homogeneity; and the use of one sample with no instrument reconfiguration. Scans and/or applications are described that measure texture, strain, twinning, improve quantitative phase analysis, and eliminate substrate scattering.

The LD makes use of five independent computer controlled motions. These enable one to study a large fraction of that part of reciprocal space which is accessible by reflection. Instrument geometry and scans are described in terms of α, θ and reciprocal space diagrams. The effect of specimen displacement on peak position is described as are the effects of a number of geometrical factors on integrated intensity.

Type
X. XRD Techniques and Instrumentation
Information
Advances in X-Ray Analysis , Volume 36: Forty-First Annual Conference on Applications of X-ray Analysis, August 3-7, 1992 , 1992 , pp. 631 - 640
Copyright
Copyright © International Centre for Diffraction Data 1992

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References

1. Ladell, J. and Nicolosi, J., Am. Cryst. Assn. Meeting, Honolulu, HA, Abstract D 3 (1979).Google Scholar
2. Nicolosi, J., Am. Cryst. Assn. Meeting, Honolulu, HA, Abstract PB4 (1979).Google Scholar
3. Ladell, J., United States Patent number: 4,199,678 (1980).Google Scholar
4. Greenberg, B., Am. Cryst. Assn. Meeting, College Station, TX, Abstract H6(1981).Google Scholar
5. Ladell, J., Schreiner, W. and Greenberg, B., Matls. Sci. Forum, (EPDtC 1 Proc.) 79-82: (323) 1991, Trans Tech Publications, Zurich.Google Scholar
6. Flinn, P. A. and Waychunas, G. A., J. Vac. Sci. Technol., B6(6):1749(1988).Google Scholar
7. Kobayashi, Y., PICXAM Congress, Honolulu, HA, Abstract D37, (1991).Google Scholar
8. Greenberg, B., J. Appl. Cryst. 10: 487 (1977).Google Scholar
9. Mack, M. and Parrish, W., Acta Cryst. 23: (691) 1967,Google Scholar