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Some Comments on the Beta-Excited X-Ray Source

Published online by Cambridge University Press:  06 March 2019

Luther E. Preuss*
Affiliation:
Edsel B. Ford Institute for Medical Research, Detroit, Michigan
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Abstract

The potential of the beta-ray excited X-ray source was evaluated in the search for a small, low energy, planar source for gross apposition studies. Such a. source utilizes the familiar phenomena wherein target impingement by particulate radiation from certain pure beta emitters is utilized for the production o£ useful bremsstrahlung and characteristic X-radiation. Some of the favorable attributes of such a source are; simplicity of design and fabrication, diminutive size, stability, low cost, zero power consutnption and the gamut of synthetic radioisotopes with which they may be powered. This paper deals with the preliminary development of such a beta-excited source for application to apposition radiography as well as with the small, compound source-target.

The design of such a source type is concerned with certain stimulating problems, some of which are; development of adequate photon intensity, reduction of excessive white radiation production, shielding for scattered and spurious radiation, target and source s elf-absorption, Simple illustrations of source-target geometries are reviewed both for compound and separate source-target design. Some resolution studies for the gross apposition source are shown, plus some exposures made with compound sources. The available synthetic isotopes are described and preliminary applications with P32 , Sr90, Y90 and Pm147 sources are outlined. The paper is divided into two portions; one, a brief review of theory and design; two, construction and results for the apposition and compound source.

Type
Research Article
Copyright
Copyright © International Centre for Diffraction Data 1957

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References

1. Leboeuf, M. B., and Stark, B. T., G. E. Report HW-31961, 1954.Google Scholar
2. Reiffel, L., Nucleonics, 13, 3, pp 2224, 1955.Google Scholar
3. Coleman, E. W., Brownell, L. E., Purohit, S. N., Report 2471-1-F, 1956.Google Scholar
4. Hollander, J. M., Perlman, I., Seaborg, G. T., Reviews of Modern Physics, 25, 2, pp 613631, 1953.Google Scholar
5. Graham, R. L., et al., Canadian Journal of Physics, 30, 459, 1952.Google Scholar
6. Liden, K., Starfelt, N., Arkiv für Fysik, 7 (9), 109, 1953.Google Scholar
7. Acton, G. H., Procedures of the Cambridge Philosophical Society, 23, 935, 1927.Google Scholar
8. Bramson, S., Zeitzschrift fur Physik, 66, 721, 1930.Google Scholar
9. Stahel, E., and Guillissen, J., Journal De Physique et le Radium, 1, 12, 1940.Google Scholar
10. Wu, C. S., Physical Review, 59, 481, 1941.Google Scholar
11. Bolgiano, P., et al., Physical Review, 89, 679, 1953.Google Scholar
12. Boehm, F., and Wu, C. S., Physical Review, 90, 369, 1953.Google Scholar
13. Novey, T. B., Physical Review, 89, 672, 1953.Google Scholar
14. Michalowicz, J., Journal de Physique et le Radium, 15, 156, 1954.Google Scholar
15. von Droste, G. F., Zeitzschrift für Physik, 104, 474, 1936.Google Scholar
16. Bradt, H., Helvetia Physica Acta, 19, 22, 1946.Google Scholar
17. Liden, K., Arkiv fur Fysik, 7, 193, 1954.Google Scholar
18. Renard, G., Journal de Physique et le Radium, 14, 361, 1953.Google Scholar
19. Edward, J. E. and Pool, M. L., Physical Review, 69, 549, 1946.Google Scholar
20. Preuss, L. E., 1955 Vacuum Symposium Transactions pp 7-21, CVT copyright 1956.Google Scholar