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Crystal Structure, Short-Range Oxygen Defects, and Water Adsorption in La- and Nd-Modified ZrO2

Published online by Cambridge University Press:  22 February 2011

C.-K. Loong ,
J. W. Richardson JR. ,
L. E. Iton  and
M. Ozawa
C.-K. Loong
Affiliation:
ARGONNE National Lab., Argonne, IL 60439, U. S. A.
J. W. Richardson JR.
Affiliation:
ARGONNE National Lab., Argonne, IL 60439, U. S. A.
L. E. Iton
Affiliation:
ARGONNE National Lab., Argonne, IL 60439, U. S. A.
M. Ozawa
Affiliation:
Nagoya Institute of Technology, Tajimi, Gifu, 507, Japan.
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Abstract

Doping Rare-earth (RE) elements to ZrO2 helps stabilize the cubic and tetragonal phases and improves resistance to thermal shock and sintering at high temperatures. Since a RE ion has a lower valency (3+) than Zr ion (4+), oxygen vacancies are formed to preserve electroneutrality. We have studied the crystal structure of La0.1Zro.9O1.95 and Nd0.1Zr0.9O1.95 by neutron diffraction and examined the associated oxygen defects by a Fourier transform of the filtered residual diffuse scattering. The hydration process was investigated by inelastic neutron-scattering measurements of the hydrogen vibrational density of states of the surface hydroxyl groups and physisorbed water on these fine powders. We compare the O-H stretch vibrations from samples with only surface hydroxyl groups to multilayer coverage of water molecules. The decreasing energies and increasing widths of the O-H stretch bands with increasing H2O coverage indicate the influence of hydrogen bonding on the motion of water molecules. Similar elastic and inelastic experiments were also performed on a high surface-area pure ZrO2 powder.

Type
Research Article
Information
MRS Online Proceedings Library (OPL) , Volume 376: Symposium BB – Neutron Scattering in Materials Science , 1994 , 627
Copyright
Copyright © Materials Research Society 1995

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References

REFERENCES

1 Ozawa, M. and Kimura, M., J. Less-Common Metals, 171, (1991) 143.Google Scholar
2 Loong, C-K., Richardson, J. W. Jr., Ozawa, M. and Kimura, M., J. Alloys and Compounds 207/208 (1994) 174.Google Scholar
3 Toukan, K., Ricci, M. A., Chen, S.-H., Loong, C.-K., Price, D. L., and Teixerira, J., Phys. Rev. A37 (1988) 2580; and M. A. Ricci, S.-H. Chen, D. L. Price, C.-K. Loong, K. Toukan, and J. Teixeira, Physica 136B (1986) 190.Google Scholar
4 Catlow, C. R. A., Chadwick, A. V., Greaves, G. N., and Moroney, L. M., J. Am. Ceram. Soc., 89, (1986) 272.Google Scholar
5 Steele, D. and Fender, B. E. F., J. Phys. C7, (1974) 1.Google Scholar
6 Morinaga, M., Cohen, J. B., and Faber, J. Jr., Acta Cryst. A35, 789 (1979), and ibid, A36, (1980) 520.Google Scholar
7 Horiuchi, H., Schultz, A. J., Leung, P. C. W., and William, J. M., Acta Cryst. B40, (1984) 367.Google Scholar
8 Dexpert-Ghys, J., Faucher, M., and Caro, P., J. Solid State Chem. 54, (1984) 179.Google Scholar
9 Tret’yakov, N. E., Pozdnyakov, D. V., Oranskaya, O. M., and Filimonov, V. N., Russ. J. Phys. Chem. 44 (1970) 596.Google Scholar