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Dynamic Characterization in Advanced Manufacturing

Published online by Cambridge University Press:  06 March 2019

Robert L. Snyder  and
Bin-Jiang Chen
Robert L. Snyder
Affiliation:
Institute of Ceramic Superconductivity NYS College of Ceramics, Alfred University Alfred, NY 14802
Bin-Jiang Chen
Affiliation:
Institute of Ceramic Superconductivity NYS College of Ceramics, Alfred University Alfred, NY 14802
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Abstract

The coming era of reduced defense funding will dramatically alter the way in which advanced materials develop. In the absence of large funding researchers must concentrate on reducing the time that the R&D of a new materia) consumes. One way in which speed may be achieved is via the development of very fast dynamic characterization procedures which can rapidly and intelligently monitor and optimize the formation of a desired microstructure. Another potential advantage to this approach is its ability to characterize the actual amount of material which goes into a final product; permitting a rapid transition from R&D to manufacturing by avoiding the problems associated with scale-up. Example high-temperature dynamic characterization procedures have been applied to the problem of trying to improve the current carrying capacity of the YBa2Cu3O7-8 ceramic superconductor by melt-texturing. These procedures have led to a technique for the preparation of specimens with Jc on the order of 10,000 A/cm2.

Type
I. Dynamic Characterization of Materials by Powder Diffraction
Information
Advances in X-Ray Analysis , Volume 38: Forty-third Annual Conference on Applications of X-ray Analysis , 1994 , pp. 1 - 8
Copyright
Copyright © International Centre for Diffraction Data 1994

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References

1. Taylor, J. A. T., Sainamthip, P., and Dockery, D. F., “Sintering time and temperature for Ba2YCu3O7-δ superconductors”; Mater. Res. Soc. Symp. Proc. 99, pp. 663-66 (1988).Google Scholar
2. Jin, S., Tiefel, T. H., Sherwood, R. C., Davis, M. E., van Dover, R. B., Kammlott, G. W., Fastnacht, R. A., Keith, H. D., “High critical currents in Y-Ba-Cu-0 superconductors,” Appl. Phys. Lett. 52[24] 2074-6 (1988).Google Scholar
3. Jin, S., Tiefel, T. H., Sherwood, R. C., van Dover, R. B., Davis, M. E., Kammlott, G. W., “Melt-textured growth of polycrystalline YBa2Cu30rs with high transport Jc at 77 K,” Phys. Rev. B. Condens. Matter 37 7850-3 (1988).Google Scholar
4. Salama, K., Selvamanickam, V., Gao, L., and Sun, K., “High current density in bulk YBa2Cu30* superconductor,” Appl. Phys. Lett. 54[23] 2352-4 (1989).Google Scholar
5. Kase, J., Shimoyama, J., Yanagisawa, E., Kondoh, S., Matsubara, T., Morimoto, T., and Suzuki, M., “Preparation of Y-Ba-Cu-O superconductors with high critical current density by unidirectional melt solidification,” Jpn. J. Appl. Phys. Part 2 29[2] 277-L279 (1990).Google Scholar
6. Gobel, H. E., “The use and accuracy of continuously scanning position-sensitive detector data in X-ray powder diffraction”, Adv. X-Ray Anal. 24, 123138 (1982).Google Scholar
7. Rodriguez, M.A., Chen, B.J., and Snyder, R.L., “The Formation Mechanism of Melt-Textured YBa2Cu3O7-δ ,” Physica C 195 185194 (1992).Google Scholar
8. Snyder, R.L., Rodriguez, M.A., Chen, BJ., Matheis, D.P., Gobel, H.E., Zoro, G., and Seebacher, B., “Analysis of YBa2Cu307°5 Peritectic Reactions and Orientation by High-Temperature XRD and Optical Microscopy,” Adv. X-ray Anal. 35, 623632 (1992).Google Scholar
9. Chen, B.J., Rodriguez, M.A., Misture, S.T., and Snyder, R.L., “Direct Observation of Textured YBa2Cu307»8 Crystal Growth form the Melt,” Physica C 198 118124 (1992).Google Scholar
10. Rodriguez, M.A., Snyder, R.L., Chen, B.J., Matheis, D.P., Misture, S.T., Frechette, V.D., Zorn, G., Gobel, H.E., and Seebacher, B., “The High-Temperature Reactions of YBa2CLn07“6,” Physica C, 205 4350 (1993).Google Scholar
11. Chen, B.J., Rodriguez, M.A., Misture, S.T., and Snyder, R.L., “Effect of Undercooling Temperature on the Solidification Kinetics and Morphology of YBCO During Melt Texturing,” Physica C 217 367375 (1993).Google Scholar
12. Aselage, T., and Keefer, K., “Liquidus relations in Y-Ba-Cu oxides,” J. Mater. Res. 3[6] 1279-91 (1988).Google Scholar
13. Roth, R. S., Davis, K. L., and Dennis, J. R., “Phase equiiibria and crystal chemistry in the system Ba-Y-Cu-OAdv. Ceram. Mater. 2[3B] 303-12 (1987).Google Scholar
14. Roth, R. S., Rawn, C. J., Beeca, F., Whitler, J. D., and Anderson, J. O., “Phase equilibria in the system Ba-Y-Cu-O-CO2 in air“; pp. 1426 in Ceramic Superconductors II. Edited by Yan, M. F.. American Ceramic Society, Westerville, OH, 1988.Google Scholar
15. Lee, B. and Lee, D. N., “Thermodynamic evaluation for the Y2O3-BaO-CuOx system,” J. Am. Ceram. Soc, 74[1] 7884 (1991).Google Scholar
16. Lay, K. W. and Renlund, G. M., “Oxygen pressure effect on the Y203-BaO-CuO liquidus,” J. Am. Ceram. Soc. 73[5] 1208-13 (1990).Google Scholar
17. Matheis, D. P., Misture, S. T. and Snyder, R. L., “Melt—Texture Processing and High-Temperature Reactions of Bi-2212 Thick Films,” Physica C 217 [3&4] 319325 (1993).Google Scholar
18. Snyder, R. L., “The Use of Reference Intensity Ratios in X-ray Quantitative Analysis,” Powder Diffraction, 7[4] 186193 (1992).Google Scholar