不同施主掺杂对(Sr_(0.3)Ba_(0.7))TiO_3系热敏LPTC电阻率的影响

本文研究了 Nb2 O5、Y2 O3 或 Sb2 O3 不同施主掺杂对 Sr0 .3 Ba0 .7) Ti O3 热敏陶瓷 LPTCR的影响 ,并讨论了不同施主掺杂的不同半导化机理。发现在本实验条件下掺 Nb的 (Sr0 .3 Ba0 .7) Ti O3 热敏陶瓷为缓变形 LPTC,掺 Sb和 Y的 (Sr0 .3 Ba0 .7) Ti O3 热敏陶瓷为突变型 LPTC,且掺 Sb的 LPTC线性度最好 ,线性温区较宽。

La掺杂Ba_(0.67)Sr_(0.33)TiO_3陶瓷高介电常数机制探讨

添加稀土元素是提高Ba_(0.67)Sr_(0.33)TiO_3陶瓷材料介电性能的一种最常用有效的方法。本文着重研究了La掺杂诱发Ba_(0.67)Sr_(0.33)TiO_3高介电常数机制。研究表明:适量的稀土La掺杂(0.2≤x≤0.7)使陶瓷介电常数显著提高,显著改善了介电温度稳定性。根据电流-电压(J-V)特性可知,适量La掺杂可使陶瓷达到最佳半导化,掺量太少或太多时陶瓷具有良好绝缘性。通过肖特基(Schottky)势垒模型及电学微观结构模型分析发现表面或晶界势垒高度、耗尽层厚度和晶粒尺寸是影响材料介电常数的主要因素。

Ca、Bi掺杂对Ba_(0.67)Sr_(0.33)TiO_3陶瓷结构与介电性能的影响

为提高Ba0.67Sr0.33Ti O3陶瓷介电性能、降低成本,采用低熔点化合物掺杂。利用X射线衍射仪(XRD)和扫描电子显微镜(SEM)等研究了Ca、Bi掺杂对Ba0.67Sr0.33Ti O3陶瓷微观结构与性能的影响。研究发现,Ca、Bi掺杂使Ba0.67Sr0.33Ti O3陶瓷烧结温度显著降为1 100℃,且有效抑制了晶粒的生长。Ca、Bi掺杂明显改善了Ba0.67Sr0.33Ti O3陶瓷温度稳定性,当超出一定固溶限度(x>6%)时,介电常数温度稳定的范围已无显著改善。

Ca、Bi掺杂Ba_(0.67)Sr_(0.33)TiO_3陶瓷弛豫特性研究

通过低成本固相法制备了Ca、Bi掺杂Ba_(0.67)Sr_(0.33)TiO_3陶瓷.利用透射电子显微镜(TEM)和阻抗分析仪分析技术,详细研究了Ca、Bi掺杂Ba_(0.67)Sr_(0.33)TiO_3陶瓷的弛豫特性.研究发现Ca、Bi掺杂使BST陶瓷呈现显著的铁电弛豫行为,且随着掺杂量的增加,介电峰弥散程度和弛豫强度逐渐增强.

高温PTC陶瓷研究进展

概述了高温ＰＴＣ陶瓷近几年来的研究进展，着重介绍了（Ｂａ、Ｐｂ）ＴｉＯ３高温ＰＴＣ陶瓷体系中Ｐｂ对居里点移动的影响，以及掺杂种类和陶瓷制备工艺等方面的研究进展，简要论述了ＰＴＣＲ的唯象分析理论，展望了高温ＰＴＣ陶瓷的研究前景。

P-E hysteresis loop going slim in Ba0.3Sr0.7TiO3-modified Bi0.5Na0.5TiO3 ceramics for energy storage applications

(Ba0.3Sr0.7)x(Bi0.5Na0.5)1-xTiO3(BSxBNT,x=0.3–V0.8)ceramics were prepared to investigate their structure,dielectric and ferroelectric properties.BSxBNT ceramics possess pure perovskite structure accompanied from a tetragonal symmetry to pseudo-cubic one with the increase of x value,being confirmed by X-ray diffraction(XRD)and Raman results.The Tm corresponding to a temperature in the vicinity of maximum dielectric constant gradually decreases from 110℃(x=0.3)to-45℃(x=0.8),across Tm=36℃(x=0.5)with a maximum dielectric constant(ɛr=5920@1 kHz)around room temperature.The saturated polarization Ps gradually while the remnant polarization Pr sharply decreases with the increase of x value,making the P-E hysteresis loop of BSxBNT ceramics goes slim.A maximum difference between Ps and Pr(Ps-Pr)is obtained for BSxBNT ceramics with x=0.5,at which a high recoverable energy density(Wrec=1.04 J/cm3)is achieved under an applied electric field of 100 kV/cm with an efficiency ofη=77%.Meanwhile,the varied temperature P-E loops,fatigue measurements,and electric breakdown characteristics for the sample with x=0.5 indicate that it is promising for pulsed power energy storage capacitor candidate materials.