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Micro-Raman Study of Sol-Gel Grown Pmn-PT Thin Films

Published online by Cambridge University Press:  21 February 2011

E. Ching-Prado ,
R. W. Tao ,
A. R. Guo ,
R. S. Katiyar  and
A. S. Bhalla
E. Ching-Prado
Affiliation:
Department of Physics, Univ. of Puerto Rico, Rio Piedras, P.R 00931-3343.
R. W. Tao
Affiliation:
Department of Physics, Univ. of Puerto Rico, Rio Piedras, P.R 00931-3343.
A. R. Guo
Affiliation:
Department of Physics, Univ. of Puerto Rico, Rio Piedras, P.R 00931-3343.
R. S. Katiyar
Affiliation:
Department of Physics, Univ. of Puerto Rico, Rio Piedras, P.R 00931-3343.
A. S. Bhalla
Affiliation:
Materials Research Laboratory, Penn State Univ., University Park, PA 16802
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Abstract

Thin films of 0.7Pb(Mg1/3Nb2/3)O3-0.3PbTiO3 (PMN-PT) were prepared by sol-gel technique and deposited on platinum coated-silicon wafer. The thicknesses of the two films were ∼400 nm and ∼550 nm, respectively. Micro-Raman spectra of the PMN-PT films show strong broad bands centered at 50, 136, 276, 450, 510, 556, and 790 cm−1, which are characteristic of PMN formation. Temperature dependent Raman scattering from 290K to 70K did not show any significant change in the bandwidth of the peaks, meaning thereby that the relaxation times of these phonons are practically temperature independent. The bands are interpreted as due to a break down in the phonon momentum conservation within the Brillouin zone, which is associated with some degree of disorder in the material. As a result, the Raman spectrum is a weighted average of the density of phonon states. Micro-Raman measurements in many different places on the films clearly indicate that they are homogeneous. In addition, the differences found in the Raman spectra of the films, particularly the band at 790 cm−1 is discussed. FT-1R measurements of the PMN-PT films present two broad bands around 260 and 550 cm−1, which are characteristic of perovskite structure and are primarily due to motions of oxygen ions. Also, these bands are compared with those found in PMN single crystal, and with those found in other similar systems, such as PLZT and PSN. SEM and XRD techniques have been used for the structural characterization.

Type
Research Article
Information
MRS Online Proceedings Library (OPL) , Volume 392: Symposium U – Thin Films for Integrated Optics Applications , 1995 , 273
Copyright
Copyright © Materials Research Society 1995

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References

1- Wood, V.E., Busch, J.R., Ramamurthi, S.D., and Swartz, L., J. Appl.,71 4557 (1992).Google Scholar
2- Ravindranathan, P., Komamneni, S., Bhalla, A. S., and Cross, L.E., Ferroelectrics Lett. 12 29 (1990).Google Scholar
3- Choi, S.W., Shrout, T.R., Jang, S.J., and Bhalla, A.S., Ferroelecirics, 100 29 (1989).Google Scholar
4- Ching-Prado, E., Tao, R.W., Katiyar, R. S., and Bhalla, A.S., in Ferroelecirics Thin Films IV, MIRSFall Meeting, Boston 1994 (to be published).Google Scholar
5- Karamyan, A.A. and Krainik, N.N., Sov. Phys. Solid State, 15 1687 (1974).Google Scholar
6- Smolensky, G.A., Siny, I.G., Pisarev, R.V., and Kuzminov, E.G., Ferroelectrics, 12 135 (1976).Google Scholar
7- Husson, E., Abello, L., and Morell, A., Mat. Res. Bull., 25 539 (1990).Google Scholar
8- Idink, H., and White, W.B., J. Appl. Phys., 76 1789 (1994).Google Scholar
9- Zelezny, V., Petzelt, J., Volkov, A.A., and Ozolinsh, M., Ferroelectrics, 109 149 (1990).Google Scholar