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The Crystal Structure of Pressure-Induced Phases of In2Te3and Ga2Te3

Published online by Cambridge University Press:  10 January 2013

N.R. Serebryanaya
N.R. Serebryanaya
Affiliation:
Institute for High Pressure Physics of USSR Academy of Sciences, 142092, Troitsk, Moscow region, USSR
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Abstract

Phase transitions were found with use of an in situX-ray anvil-type of apparatus with a boron annulus at pressures up to 12 GPa. The disordering of vacancies in the In sub-structure, or αβtransition, was found in In2Te3at p > 1.9 GPa. The next transformation from the β-form into the Bi2Te3type of structure was observed in both sesquitellurides at 2.0 GPa and 5.0 GPa for In2TGe3and Ga2Te3respectively. The In2Te3metastable phase of the Bi2Te3resulted from heating up to 200° C at p > 4.0 GPa, and it remained in a normal condition on release of the pressure. The X-ray powder diffraction data of pressure-induced phases, volume changes and bulk modulus of both sesquitellurides are given. The compressibility anisotropy of the layer pressure-induced phase was observed. The mechanism of the crystal structure transformation from the face-centered cubic structure into the Bi2Te3type is proposed to be due to the displacement of atoms from the space diagonal of the cube [111] into [112]-cubic direction and the rhombohedral distortion of the angle between these directions.

Type
Research Article
Information
Powder Diffraction , Volume 7 , Issue 2 , June 1992 , pp. 99 - 102
Copyright
Copyright © Cambridge University Press 1992

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References

Borg, I.Y.& Smith, D.K.(1967). J. Phys. Chem. Solids 28, 4954.CrossRefGoogle Scholar
Bose, D.N., Sen, S., Joshi, D.K., & Vaidya, S.N.(1982). Materials Lett. 1, 6163.CrossRefGoogle Scholar
Chattopadhyay, T., Werner, A., von Schnering, H.G.& Pannetier, J.(1984). Rev. Phys. Appl. 19, 807813.CrossRefGoogle Scholar
Geller, S., Jayaraman, A., & Hull, G.W. Jr,. (1965). J. Phys. Chem. Solids, 26, 353361.CrossRefGoogle Scholar
Jamieson, J.C., & Lawson, A.W.(1962). J. Appl. Phys. 33, 776780.CrossRefGoogle Scholar
Kabalkina, S.S., & Troitskaya, Z.V.(1963). Dokl. Acad. of Sci. USSR, 151, 10681070.Google Scholar
Kabalkina, S.S., Vereshchagin, L.F.& Lityagina, L.M.(1967). Dokl. Acad. of Sci. USSR, 176, 10441047.Google Scholar
Kabalkina, S.S., Serebryanaya, N.R.& Vereshchagin, L.F.(1968). Fiz. Tverdogo Tela. USSR 10, 733739.Google Scholar
Woolley, J.C., Pamplin, B.R., & Holmes, P.J.(1959). J. Less-Common Metals, 1, 362376.CrossRefGoogle Scholar
Wyckoff, R.W.G.(1964). Crystal Structures, Vol.2, 2931. John Wiley & Sons, New York.Google Scholar