New pressure induced phase transitions in mullite-type Bi2(Fe4–xMnx)O10–δ complex oxides

Patricia E. Kalita; Andrew L. Cornelius; Kristina E. Lipinska; Michael W. Lufaso; Zachary R. Kann; Stanislav Sinogeikin; Oliver A. Hemmers; Hartmut Schneider

doi:10.3139/146.110719

Published by De Gruyter June 11, 2013

New pressure induced phase transitions in mullite-type Bi₂(Fe₄_–_xMn_x)O₁₀_–_δ complex oxides

Patricia E. Kalita , Andrew L. Cornelius , Kristina E. Lipinska , Michael W. Lufaso , Zachary R. Kann , Stanislav Sinogeikin , Oliver A. Hemmers and Hartmut Schneider

From the journal International Journal of Materials Research

https://doi.org/10.3139/146.110719

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Abstract

Single phased mullite-type Bi₂Fe₄_–_xMn_xO₁₀_–_δ mixed crystals (0.25 ≤ x ≤ 3.125) and the end-member Bi₂Fe₄O₉, synthesized from the oxides by reaction sintering up to 825°C, were studied at high-pressures in order to probe their high-pressure behavior and any possible structural phase transitions. In-situ synchrotron radiation-based powder X-ray diffraction was carried out in a diamond anvil cell, under quasi-hydrostatic conditions, up to a pressure of about 20 GPa at room temperature for each sample. A pressure-induced phase transition was found in all samples. The transition appeared spread over a pressure range and was not completed at the top investigated pressure. This is the first report of a pressure-induced phase transition in Bi₂Fe₄_–_xMn_xO₁₀_–_δ mixed crystals.

Keywords: Mullite; Oxide; High-pressure; Phase transition; X-ray diffraction

* Correspondence address P. Kalita University of Nevada Las Vegas, Department of Physics and Astronomy, High Pressure Science and Engineering Center 4505 Maryland Parkway, Box 4002 Las Vegas, NV, 89154-4002, USA Tel.: +1(702)6880586 Fax: +1(702)8950804 E-mail: mullites@gmail.com alternate E-mail: patrizia@physics.unlv.edu

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Received: 2011-12-1

Accepted: 2012-1-26

Published Online: 2013-06-11

Published in Print: 2012-04-01

New pressure induced phase transitions in mullite-type Bi₂(Fe₄_–_xMn_x)O₁₀_–_δ complex oxides

Abstract

References

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