4.7 Article

Phase transformations in an Aurivillius layer structured ferroelectric designed using the high entropy concept

Journal

ACTA MATERIALIA
Volume 229, Issue -, Pages -

Publisher

PERGAMON-ELSEVIER SCIENCE LTD
DOI: 10.1016/j.actamat.2022.117815

Keywords

High entropy; Aurivillius; Ferroelectric; Domain; Phase transition

Funding

  1. International Cooperation Foundation of Shaanxi Province [2020KW-032]
  2. China Scholarship Council (CSC) [201706370172, 201604 91054 9, 201706370217]
  3. Building-up Centre for advanced materials application of the Slovak Academy of Sciences, ITMS [313021T081]
  4. ERDF
  5. Slovak Research and Development Agency [APVV-20-0124]
  6. Grant Agency VEGA [2/0144/21]

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6ABTO is a single phase four-layer Aurivillius structured ferroelectric ceramic with complex ferroelectric behavior and high Curie point, showing unique current-electric field behavior. Despite the disorder between component cations, 6ABTO does not exhibit relaxor ferroelectric behavior, suggesting that relaxor behavior may be more associated with the thermal stability of dipoles.
A single phase four-layer Aurivillius structured ferroelectric ceramic, (Ca(0.2)Sr(0.2)Ba(0.2)Pb(0.2)Nd(0.1)Na0.1)Bi4Ti4O15 (6ABTO) was obtained using a high entropy design concept. The material, which has orthorhombic symmetry in space group A2(1)am at room temperature, has Ca2+, Sr2+, Ba2+, Pb2+, Nd3+ and Na+ distributed not only on the A sites of the perovskite layer but also in the bismuthate layer. 6ABTO shows complex ferroelectric behavior, with a Curie point of 557 & nbsp;C. Four current peaks are observed in the current -electric field curve. These peaks are attributed to a combination of a field induced phase transition and domain wall switching, which is the first reported occurrence of such current -electric field behavior for an Aurivillius structured ferroelectric material. Despite the level of disorder between the A site cations in the perovskite layer and the Bi positions in the bismuthate layer, 6ABTO does not show the relaxor ferroelectric behavior, that is commonly observed in cases of such disorder. This suggests that relaxor behavior in ferroelectrics, may be more associated with the thermal stability of dipoles, rather than the presence of polar nano-regions formed as a result of chemical disorder. The nature of the high entropy effect in 6ABTO is discussed through comparison of results from isostructural compositions containing 5, 4 and 3 of the component cations & nbsp;(c) 2022 Acta Materialia Inc. Published by Elsevier Ltd. All rights reserved.

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