介绍了LiTaO3的基本性质,综述了LiTaO3基压电陶瓷体系的制备方法、压电铁电性能及应用背景,指出了目前相关研究的重点和难点,并展望了LiTaO3基压电陶瓷今后的研究和发展方向.
参考文献
| [1] | SWARTZ S L;SHROUT T R .Electronic ceramics R&D in the U.S,Japan,Part Ⅰ:Patent history[J].American Ceramic Society Bulletin,1997,76(07):59-65. |
| [2] | 肖定全;干福熹.信息材料[M].天津:天津大学出版社,2000 |
| [3] | TAKENAKA T .Lead-free piezoelectric ceramics for clean environment[J].Materials Integration,2002,15:89-100. |
| [4] | 尹奇异,赁敦敏,肖定全,朱建国,余萍.无铅压电陶瓷及其应用研究[J].金属功能材料,2004(06):40-45. |
| [5] | 赁敦敏,肖定全,朱建国,余萍,鄢洪建.无铅压电陶瓷研究开发进展[J].压电与声光,2003(02):127-132. |
| [6] | 许煜寰.铁电与压电材料[M].北京:科学出版社,1978 |
| [7] | SINCLAIR D C;WEST A R .Electrical properties of LiTaO3 single crystal[J].Physical Review B,1989,39:13486-13492. |
| [8] | SHIMADA S;KODAIRA K;MATSUSHITA T .Sintering LiTaO3 and KTaO3 with the aid of manganese oxide[J].Journal of Materials Science,1984,19:1385-1390. |
| [9] | N. Bamba;T. Yokouchi;J. Takaoka .Effects of CaTiO_3 on Electrical Properties in LiTaO_3 Ceramics[J].Ferroelectrics: Letters Section,2004(1):135-138. |
| [10] | BIRNIE D P .Model for the ferroelectric transition in nonstoichiometric lithium niobate and lithium tantalite[J].Journal of the American Ceramic Society,1991,74(05):988-993. |
| [11] | BARNS R L;CARRUTHERS J R .Lithium tantalite single crystal stoichiometry[J].Journal of Applied Crystallography,1970,3:395-399. |
| [12] | HUANOSTA A;ALVAREZ E;VILLAFUERTECASTREJ(O)N M E et al.Electrical properties of Mg-doped LiTaO3 ceramics[J].J Mater Res Bull,2004,39:2229-2239. |
| [13] | YE Z G;VON DER MUHLL R;RAVEZ J et al.Dielectric,piezoelectric and pyroelectric studies of LiTaO3-derived ceramics sintered at 900℃ following the addition of (LiF + MgF2)[J].Journal of Materials Research,1988,3(01):112-115. |
| [14] | YE Z G;VON DER MUHLL R;RAVEZ J .New oxyfluorides and highly densified ceramics related to LiTaO3[J].Journal of Physics and Chemistry of Solids,1989,50:809-812. |
| [15] | YE Z G;VON DER MUHLL R;RAVEZ J.Sintering mechanism of LiTaO3 ceramics by the addition of Lithium and Magnesium Fluorides[J].IEEE |
| [16] | BONNET J P;RAVEZ J;JOO G T et al.Correlation between sintering conditions and microstructure in ceramics of composition Li0.8Mg0.2Ta0.8Ti0.2O3[J].Journal of Materials Research,1988,3:387-390. |
| [17] | YE Z G;VON DER MUHLL R et al.Nouveaux materiaux oxyfluores ferroelectriques derives de LiTaO3[J].Materials Research and Bulletin,1986,21:1361-1367. |
| [18] | YE Z G;VON DER MUHLL R;RAVEZ J .Etudes physico-chimiques dune nouvelle phase hydroxofluoree ferroelectrique de type LiTaO3[J].Journal of Physics and Chemistry of Solids,1988,49:1153-1158. |
| [19] | BASKIN Y;SCHELL D C .Phase studies in the binary system MgO.Ta2O5[J].Journal of the American Ceramic Society,1963,46:174-177. |
| [20] | BERTAUT E F;CORLISS L;FORRAT F et al.Etudes de niobates et tantalates de metaux de transition bivalents[J].Journal of Physics and Chemistry of Solids,1961,21:234-251. |
| [21] | ZRIOUIL M;ELOUADI B;RAVEZ J;HAGENMULLER P .Effect of Zirconium Substitution on the Crystallographic and Dielectric Properties of LiTaO3[J].Journal of Solid State Chemistry,1984,51:53-58. |
| [22] | NEURGAONKAR R R;LIM T C;STAPLES E J .Structural and dielectric properties in the system LiTaO3 -CaZrO3[J].Materials Research and Bulletin,1978,13(06):635-642. |
| [23] | ELOUADI B;ZRIOUIL M;RAVEZ J;HAGENMULLER P .Some new non-stoichiometric ferroelectric phases appearing close to LiTaO3 in the ternary system Li2O-Ta2O5-(TiO2)2[J].Materials Research and Bulletin,1981,16(09):1099-1106. |
| [24] | HUANOSTA A;WEST A R .The electrical properties of ferroelectric LiTaO3 and its solid solutions[J].Journal of Applied Physics,1987,61(12):5386-5391. |
| [25] | NEURGAONKAR R R;LIM T C;CROSS L E .An exploration of the limits of stability of the LiNbO3 structure field with A and B site cation substitutions[J].Ferroelectrics,1980,27:63-66. |
| [26] | LIU Y G;JIA D C;ZHOU Y .Microstructure and mechanical properties of a lithium tantalite-dispersed-alumina ceramic composite[J].Ceramics International,2002,28:111-114. |
上一张
下一张
上一张
下一张
计量
- 下载量()
- 访问量()
文章评分
- 您的评分:
-
10%
-
20%
-
30%
-
40%
-
50%