2021年第68回応用物理学会春季学術講演会

講演情報

一般セッション(口頭講演)

9 応用物性 » 9.1 誘電材料・誘電体

[18p-Z16-1~16] 9.1 誘電材料・誘電体

2021年3月18日(木) 13:30 〜 18:00 Z16 (Z16)

塚田 真也(島根大)、上野 慎太郎(山梨大)、森本 貴明(防衛大)

15:45 〜 16:00

[18p-Z16-9] Piezoelectricity Enhancement of Textured Bi-Based Ceramics by Domain Engineering

〇(P)Gopal Prasad Khanal1,2、Ichiro Fujii2、Shintaro Ueno2、Satoshi Wada2 (1.Tokyo Inst. of Tech.、2.Univ. of Yamanashi)

キーワード:Bi-based, Grain-oriented, Piezoelectric strain constant

The ceramics with grain-orientation along a crystallographic direction other than that of the spontaneous polarization direction have been reported to exhibit significantly enhanced piezoelectric properties due to domain engineering. In this study, <100>-oriented 0.11(Bi0.5K0.5)TiO3-0.23BaTiO3-0.02Bi(Mg0.5Ti0.5)O3-0.64BiFeO3 piezoelectric ceramics were prepared by the reactive templated grain growth method using small and uniform plate-like particles of layered titanate; H1.08Ti1.73O4.nH2O templates, while the randomly oriented ceramics were fabricated using a solid-state reaction method. Optimum preparation conditions for the synthesis of highly <100>-oriented piezoelectric ceramics were investigated.
The reaction system with matrix component of Bi2O3, KHCO3, BaCO3, MgO, Fe2O3 exhibited the appreciable extent of <100>-orientation (F100=79.6%, which is the highest value among the BiFeO3-based grain-oriented ceramics ever reported. The presence of perovskite-structured matrix component exhibited a negligible degree of orientation (<5%). The underlying mechanism for the difficulty in texturing due to the presence of perovskite-structured matrix components was investigated by crystal structures’ and microstructures’ analysis.
The increase of piezoelectric strain constant (d33*; evaluated from unipolar S-E curves) from 295 pm/V (randomly-oriented) to 522 pm/V (77% enhancement by domain engineering) for the <100>-oriented ceramics is comparable to that of the existing lead-based systems. The large piezoelectricity with TC>400oC strongly suggested its great potentiality on replacing lead-based systems for high-temperature actuator application.