采用TEM、SEM、ESR(电子自旋共振)结合常规压电性能测试手段研究了Cr2O3掺杂对PZT-PMN陶瓷的压电性能、微结构及畴态的影响.压电性能测试结果表明,当Cr2O3含量低于0.06Wt%时,可使Kp和Qm同时提高,这说明铬掺杂同时兼具“软掺杂”与“硬掺杂”的双重特性.此外,还发现随着烧结温度的提高,材料性能“硬化”明显.ESR谱分析表明,Cr离子主要以Cr3+和 Cr5+的方式共存,随着烧结温度的提高,它有从高价态 Cr5+或Cr6+向低价态转变的趋势,这一价态变化被认为是材料性能随烧结温度提高而“变硬”的主要原因之一.TEM图片显示,随着掺杂的Cr2O3的浓度的增大,由于氧空位或受主离子与氧空位构成的缺陷复合体对畴壁的钉扎,电畴将从正规带状畴向波纹状畴转变.
The effects of Cr2O3 addition on piezoelectric properties,microstructure and morphology of the domain of PZT-PMN ceramics
were studied by TEM, SEM, ESR and other conventional electrical methods. The measurement results of piezoelectric properties showed that the
Cr2O3 addition was effective in increasing the Kp and Qm when its concentration was below 0.06wt%, which indicated
that Cr-doped PZTMN ceramics possessed the properties of “soft” and “hard” piezoelectrics simultaneously. Furthermore, the properties were
found to get “hard” with the increase of sintering temperature even for the ceramics with the same compositions. Electron Spin Resonance (ESR)
analysis showed that Cr ion coexisted in both Cr3+ and Cr5+, and the valence change from Cr5+ or Cr6+ to Cr3+ happened
when the sintering temperature was increased, which was believed to be one of the reasons for its hardness of the properties. TEM images
revealed that, with the increment in Cr content, the normal stripe-like domain changed to wavy domain due to the domain pinning by the defect
complexes of acceptor impurities and oxygen vacancies.
参考文献
| [1] | Xu Y H. Ferroelectric Material and Their Applications. Amsterdam: North-Holland, 1991. 121--146. [2] Jaffe B, Cook W R, Jaffe H. Piezoelectric Ceramics, London and New York:Academic press 1971. 271--279. [3] Uchida N, Ikeda T. Japanese Journal of Applied Physics, 1967, 6 (11): 1292--1299. [4] Vasileva T K, Nadoliisky M M, Toshev S D. Phy. Stat. Sol.(a), 1984, 86: k109--k111. [5] Nadoliisky M M, Toshev S D, Vasileva T K. Phy. Stat. Sol.(a), 1979, 54: k145--k150. [6] Cheon C, Park J S. J. Materials Sciences Letters, 1997, 16: 2043--2046. [7] Ng Y S, Alexander S M. Ferroelectrics, 1983, 51: 81--86. [8] He L X, Li C E. Journal of Materials Sciences, 2000, 35 (1): 1--4. [9] Okazaki K, Nagata K. J. Am. Ceram. Soc., 1973, 56 (2): 82--86. [10] Lee H S, Kimura T. J. Am. Ceram. Soc., 1998, 81 (12): 3228--3236. [11] 许煜寰. 铁电与压电材料. 北京: 科学出版社, 1978. 154--155. [12] 方俊鑫, 殷之文. 电介质物理. 北京: 科学出版社, 1989. 235--240. [13] Wertz J E, Bolton J R. Electron Spin Resonance: Elementary Theory and Practical Application, New York: Mcgraw-Hill, 1972. 268--302. [14] 申泮文, 车云霞,顾翼东, 等. 无机化学(第八卷). 北京: 科学出?版社, 1998. 446--447. [15] Tan Q, Viehland D. J. Am. Ceram. Soc., 1998, 81 (2): 328--336. [16] Tan Q, Li J F, Viehland D. Phil. Mag. B, 1997, 76 (1): 59--74. |
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