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Real-Time X-Ray Diffraction For Materials Process Control

Published online by Cambridge University Press:  29 November 2013

R.E. Green Jr.
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As useful as classical x-ray diffraction techniques have been, the ability to obtain x-ray diffraction images with extremely short exposure rimes opens up new opportunities for materials scientists, including real-time materials process control. This article briefly describes state-of-the-art systems for obtaining extremely rapid and real-time x-ray diffraction images and gives several examples of their applications for materials process control.

Two generic electro-optical methods permit real-time viewing and recording of x-ray diffraction images. The first uses a low-intensity conventional x-ray tube source leading to a low-intensity diffraction image, which requires a high-gain electro-optical imaging system. The second uses either a high-intensity rotating anode, synchrotron, or flash x-ray source. Such a high-intensity source produces a high-intensity diffraction image, permitting use of a low-gain high-resolution electro-optical imaging system.

Figure 1 schematically shows two types of image intensifier tubes which have been most often used to view x-ray diffraction images. By cascading three individual first generation image tube stages (Figure 1a), light gains as high as several million can be obtained. The second generation microchannel-plate image intensifier tube (Figure 1b) is similar to a single-stage first generation device except for the extremely important addition of a microchannel plate.

Type
On-Line Nondestructive Evaluation
Information
MRS Bulletin , Volume 13 , Issue 4 , April 1988 , pp. 44 - 48
Copyright
Copyright © Materials Research Society 1988

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References

1.Green, R.E. Jr., in Advances in X-Ray Analysis, Vol. 14, edited by Barrett, C.S., Newkirk, J.B., and Ruud, C.O. (Plenum, New York, 1971) p. 311337.Google Scholar
2.Green, R.E. Jr., in Advances in X-Ray Analysis, Vol. 20, edited by McMurdie, H.F., Barrett, C.S., Newkirk, J.B., and Ruud, C.O. (Plenum, New York, 1977) p. 221235.CrossRefGoogle Scholar
3.Winter, J.M. and Green, R.E. Jr., in Applications of X-Ray Topographic Methods to Materials Science, edited by Weissman, S.et al. (Plenum, New York, 1984) p. 4558.Google Scholar
4.Rosemeier, R.G. and Green, R.E. Jr., Nucl. Instrum. Methods 195 (1982) p. 299301.CrossRefGoogle Scholar
5.McCaughan, D.V. and Holeman, B.R., in Charge Coupled Devices and Systems, edited by Howes, M.J. and Morgan, D.V. (John Wiley, New York, 1979) p. 241295.Google Scholar
6.Green, R.E. Jr., in Advances in X-Ray Analysis, Vol. 15, edited by Heinrich, K.J., Barrett, C.S., Newkirk, J.B., and Ruud, C.O. (Plenum, New York, 1972) p. 435445.CrossRefGoogle Scholar
7.Beczak, C., Pond, R.B. Sr., and Green, R.E. Jr., Materials Science and Engineering Department, The Johns Hopkins University (unpublished).Google Scholar
8.Tanner, B.K., X-Ray Diffraction Topography (Pergamon, New York, 1976).Google Scholar
9.Boettinger, W.J., Burdett, H.E., Kuriyama, M., and Green, R.E. Jr., Rev. Sci. Instrum., 47 (1976) p. 906911.CrossRefGoogle Scholar
10.Green, K.A. and Green, R.E. Jr., “Application of X-Ray Topography to Improved Nondestructive Inspection of Single Crystal Turbine Blades,” in Proceedings of 16th NDE Symposium (Southwest Research Institute, San Antonio, TX, 1987) (to be published).Google Scholar
11.Bilello, J.C., Chen, H., Hmelo, A.B., Liu, J.M., Birnbaum, H.K., Herley, P.J., and Green, R.E. Jr., Nucl. Instrum. Methods 215 (1983) p. 291297.CrossRefGoogle Scholar
12.Winter, J.M. Jr., Hanson, W.P., and Green, R.E. Jr., in National Synchrotron Light Source Annual Report 1986, edited by White-DePace, S. and Gmur, N. (Brookhaven National Laboratory, Upton, NY, 1986) p. 405406.Google Scholar
13.Winter, J.M. Jr. and Green, R.E. Jr., “Real-Time Monitoring of Microstructural Transformations Using Synchrotron and Flash X-Ray Topography,” in Proceedings of Symposium on Intelligent Processing of Materials and Advanced Sensors (TMS-AIME, Warrendale, PA, to be published).Google Scholar
14.Winter, J.M. Jr., Green, R.E. Jr., and Corak, W.S., “White Beam Synchrotron X-Ray Topography of Gallium Arsenide,” in Review of Progress in Quantitative Nondestructive Evaluation, edited by Thompson, D.O. and Chimenti, D.E. (Plenum, New York, to be published).Google Scholar
15.Hanson, W., “Transmission X-Ray Topography of Single Crystal Quartz Using White Beam Synchrotron Radiation,” Masters essay, Materials Science and Engineering Department, The Johns Hopkins University, 1988.Google Scholar
16.Dantzig, J.A. and Green, R.E. Jr., in Advances in X-Ray Analysis, Vol. 16, edited by Birks, L.S.et al. (Plenum, New York, 1973) p. 229241.CrossRefGoogle Scholar
17.Green, R.E. Jr., in Proceedings of Flash Radiography Symposium, edited by Bryant, L.E. Jr. (Amer. Soc. for Nondestructive Testing, Columbus, OH, 1977) p. 151164.Google Scholar
18.Green, R.E. Jr. and Rabinovich, D., in 1984 Flash Radiography Symposium, edited by Webster, E.A. Jr. and Kennedy, A.M. (Amer. Soc. for Nondestructive Testing, Columbus, OH, 1985) p. 157170.Google Scholar