采用传统的陶瓷工艺制备了MgO掺杂的Ba0.6Sr0.4TiO3(BST)陶瓷样品.系统地研究了MgO掺杂量为0.06%~0.18%的Ba0.5Sr0.4TiO3陶瓷的微结构和介电性能.XRD分析显示,在我们所选取的掺杂范围内,MgO并没有影响到BST陶瓷的主晶相钙钛矿结构,且一定量的Mg离子进入到BST的晶格中.扫描电子显微镜对样品的形貌观察揭示了,随着MgO含量的增加其晶粒尺寸逐渐减小.介电性能和介电偏压测试表明,相对未掺杂BST样品的介电损耗明显降低且居里点逐渐向低温移动,可调性随着MgO掺杂量的增加而减小,MgO的掺杂量为0.18%(质量分数)时居里温度移到-49℃,可调性为16%,且样品的居里温度在外加电场作用下向高温方向移动.微波性能测试表明MgO掺杂BST陶瓷相对未掺杂样品具有较高的Q值.
参考文献
| [1] | Sengupta L C;Sengupta S .[J].IEEE Transactions,1997,44:792-797. |
| [2] | Sengupta L C;Ngo E;Stowell S et al.Ceramic Ferroelectric Composite Materials-BSTO-Mgo[P].US 5427988,1995. |
| [3] | Chiu L H .Ceramics Ferroelectric Composite Materials with Enhanced Electric Properties BSTO-Mg Based Compound-rare Earth Oxide[P].US 6074971,2000. |
| [4] | Sengupta L C .Ceramics Ferroelectric Composite Materials-BSTO-magnesium Based Compound[P].US 5635434,1997. |
| [5] | Liang Ruihong;Dong Xianlin;Chen Ying et al.[J].Materials Chemistry and Physics,2006,95:222-228. |
| [6] | Cole M W;Joshi P C;Ervin M H et al.[J].Thin Solid Films,2000,374:34-41. |
| [7] | Chang W;Sengupta L .[J].Journal of Applied Physics,2002,92:3941-3946. |
| [8] | Jain M;Majumder S B;Katiyar R S et al.[J].Materials Letters,2003,57:4232-4236. |
| [9] | Chen Ying;Dong Xianlin;Liang Ruihong et al.[J].Journal of Applied Physics,2005,98:064107. |
| [10] | Kurchania R.IEEE International Ultrasonics[A].Canada,2004:281-284. |
| [11] | Su B;Button T W .[J].Journal of Applied Physics,2004,95:1382-1385. |
| [12] | Cole M W;Hubbard C;Ngo E et al.[J].Journal of Applied Physics,2002,92:475-483. |
| [13] | Wang Xiaohong;Lua Wenzhong;Liu Jian et al.[J].J European Ceram Soc,2006,26:1981-1985. |
| [14] | Buessem W R;Cross L E;Goswami A K .[J].Journal of The American Chemical Society,1996,49(01):33-36. |
| [15] | Liang Xiaofeng;Wu Wenbiao;Meng Yan .[J].Chinese Journal of Rare Metals,2003,B99:366-369. |
| [16] | 梁瑞红;董显林;陈莹 .[J].中国物理,2005,54:4914-4919. |
| [17] | Hakki B W;Coleman P D .[J].IEEE Transactions,1960,8:402-410. |
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%