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Temperature Gradients and Residual Porosity in Microwave Sintered Zinc Oxide

Published online by Cambridge University Press:  10 February 2011

L. P. Martin ,
D. Dadon ,
M. Rosen ,
A. Birman ,
D. Gershon ,
J. P. Calame ,
B. Levush  and
Y. Carmel
L. P. Martin
Affiliation:
Department of Materials Science and Engineering, Johns Hopkins University, Baltimore, MD.
D. Dadon
Affiliation:
Department of Materials Science and Engineering, Johns Hopkins University, Baltimore, MD.
M. Rosen
Affiliation:
Department of Materials Science and Engineering, Johns Hopkins University, Baltimore, MD.
A. Birman
Affiliation:
Laboratory for Plasma Research, University of Maryland, College Park, MD.
D. Gershon
Affiliation:
Laboratory for Plasma Research, University of Maryland, College Park, MD.
J. P. Calame
Affiliation:
Laboratory for Plasma Research, University of Maryland, College Park, MD.
B. Levush
Affiliation:
Laboratory for Plasma Research, University of Maryland, College Park, MD.
Y. Carmel
Affiliation:
Laboratory for Plasma Research, University of Maryland, College Park, MD.
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Abstract

ZnO samples were sintered in an overmoded 2.45 GHz microwave applicator. In-situ differential temperature measurements were made to allow comparison of surface and core temperatures during heating. At intermediate temperatures, near 600°C, the sample core was measured to be more than 250°C hotter than the sample surface. As the core temperature approached 1100°C, however, the difference between the surface and core temperatures diminished. Post-sintering scanning electron microscopy (SEM) showed spatial variations in the residual porosity which were consistent with the measured temperature differential. For samples sintered to intermediate temperatures, where large temperature differences persisted, there were significant gradients in the residual porosity. For samples sintered to higher temperatures, there was little residual porosity and no observable porosity gradient. Local density versus temperature behavior was obtained by correlating porosity levels measured from the micrographs with temperature measurements made during sintering. These data demonstrate a significantly lower activation energy for microwave sintering than for conventional sintering.

Type
Research Article
Information
MRS Online Proceedings Library (OPL) , Volume 430: Symposium O – Microwave Processing of Materials V , 1996 , 579
Copyright
Copyright © Materials Research Society 1996

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References

1. Several articles in MRS Bull., 18 [11], (1993).Google Scholar
2. Johnson, D. L., in Ceramic Transactions, Vol.21, Microwaves: Theory and Application in Materials Processing, Clark, D. E., Gac, F. D., and Sutton, W. H. eds. (American Ceramic Society, Westerville, OH, 1991), pp. 1728.Google Scholar
3. Clark, D. E. and Folz, D. C., in, pp. 2934.Google Scholar
4. Iskander, M. F., Andrade, O., Vikar, A., Kimrey, H., Smith, R., Lamoreaux, S., Cheng, C, Tanner, C. and Mhta, K., in, pp. 3548.Google Scholar
5. De, A., Ahmad, I., Whitney, E. D. and Clark, D. E., in, pp. 319328.Google Scholar
6. De, A., Ahmad, I., Whitney, E. Dow and Clark, D. E., in Microwave Processing of Materials HI, Snyder, W. B. Jr., Sutton, W.H., Iskander, M. F. and Johnson, D. L., eds. (Materials Research Society, Pittsburgh, PA, 1991), pp. 283288.Google Scholar
7. Hilliard, J. E. in Quantitative Microscopy, DeHoff, R. T. and Rhines, F. N., eds. (McGraw Hill, Inc., New York, 1968), pp. 4554.Google Scholar
8. Birman, A., Levush, B., Carmel, Y., Gershon, D., Dadon, D., Martin, L.P. and Rosen, M., in Ceramic Transactions, Vol.59, Microwaves: Theory and Application in Materials Processing III, Clark, D. E., Folz, D. C., Oda, S. J. and Silberglitt, R. eds. (American Ceramic Society, Westerville, OH, 1991), pp.30 5 - 312.Google Scholar
9. Birman, A., Gershon, D., Calame, J., Carmel, Y., Levush, B., Bykov, Yu. V., Eremeev, A. G., Holoptsev, V. V., Semenov, V. E., Dadon, D., Martin, L. P., Rosen, M. and Hutcheon, R., submitted to J. Appl. Phys. (1996).Google Scholar
10. Martin, L.P., Dadon, D., Gershon, D., Levush, B., Carmel, Y. and Rosen, M., in Ceramic Transactions, Vol.59, Microwaves: Theory and Application in Materials Processing III, Clark, D. E., Folz, D. C., Oda, S. J. and R. Silberglitt eds. (American Ceramic Society, Westerville, OH, 1991), pp. 39 9 - 406.Google Scholar
11. Johnson, D. L., J. Appl. Phys., 40, 192200 (1969).Google Scholar
12. Young, W. S. and Cutler, I. B., J. Am. Ceram. Soc., 53, 659663 (1970).Google Scholar
13. Woolfrey, J. L. and Bannister, M. J., J. Am. Ceram. Soc., 55, 390394 (1970).Google Scholar
14. Wang, J. and Raj, R., J. Am. Ceram. Soc., 73, 11721175 (1990).Google Scholar
15. Bagley, R.D., Cutler, I.B., and Johnson, D.L., J. Am. Ceram. Soc., 53, 136141 (1970).Google Scholar
16. Samuels, J. and Brandon, J. R., J. Mat. Sci., 27, 32593265 (1992).Google Scholar
17. Dadon, D., Martin, L. P., Rosen, M., Birman, A., Gershon, D., Calame, J. P., Levush, B. and Carmel, Y., submitted to J. Mat. Sci. and Proc. (1995).Google Scholar
18. Bannister, M. J., J. Am. Ceram. Soc., 51, 548553 (1968).Google Scholar
19. Gupta, T. K. and Coble, R.L., J. Am. Ceram. Soc., 51, 521525 (1968).Google Scholar
20. Dutta, S. K. and Spriggs, R. M., Mater. Res. Bull., 4, 797806 (1969).Google Scholar
21. Janney, M. and Kimrey, H., Mat. Res. Symp. Proc., 189, 215226 (1990).Google Scholar
22. Rybakov, K.I. and Semenov, V.E., Phys. Rev. B, 52, 30303033 (1995).Google Scholar
23. Freeman, S. A., Booske, J. H. and Cooper, R. F., Phys. Rev. Lett., 74, 20422045 (1995).Google Scholar