掺杂SrCO3对Ba4(Sm0．2Nd0．8)9．33Ti18O54微波介质陶瓷性能的影响

研究SrCO3掺杂对Ba4(Sm0.2Nd0.8)9.33Ti18O54(BSNT)材料相组成、微观结构和介电性能的影响。采用X线衍射仪(XRD)和扫描电子显微镜(SEM)表征BSNT掺杂SrCO3后陶瓷的相组成和微观结构。结果表明:SrCO3掺杂量低于4%时,SrCO3与BSNT陶瓷共熔而不产生第二相。同时发现随着SrCO3掺杂量的增加,介电常数εr和谐振频率温度系数τf近似线性增加。在BSNT陶瓷中掺杂SrCO3可以得到τf近乎于0。掺杂4%的SrCO3在1 360℃下烧结3 h,可得到介电性能最佳的BSNT陶瓷(εr=83.4,Qf=8.47 THz(4.67 GHz),τf=-2.1×10-6℃-1)。

Al_2O_3掺杂对Ba_4Sm_(9.33)Ti_(18)O_(54)陶瓷显微结构和介电性能的影响

采用固相反应法制备了Ba4Sm9.33Ti18O54（简称BST）xwt%Al2O3（x=0~1.5）微波介质陶瓷.研究了掺杂Al2O3对BST陶瓷的显微结构和介电性能的影响.扫描电镜和能谱分析结果显示：未掺杂的BST陶瓷中有少量Sm2Ti2O7相,随着增加Al2O3掺入量,Sm2Ti2O7相消失,BST陶瓷中先后产生了BaTi4O9（x≥0.6）和BaAl2Ti5O14（x≥1.0）两种新相.介电性能测试结果表明Sm2Ti2O7相的消失以及少量BaTi4O9相的形成,能显著提高BST陶瓷的Qf值,但会降低陶瓷的介电常数.当Al2O3的掺入量从0.6wt%增加到1.0wt%时,BaTi4O9相的量逐渐增加,引起BST陶瓷的Qf值略微下降.BaAl2Ti5O14相的产生会同时降低BST陶瓷的介电常数和Qf值.掺入0.6wt%Al2O3的BST陶瓷在1340℃烧结3 h后具有最佳的介电性能：εr=74.7,Qf=10980 GHz,τf=–11.8×10-6/℃.

WO_3掺杂对BST微波介质陶瓷性能的影响

采用固相反应法,研究了WO_3掺杂对Ba_4Sm_(9.33)Ti_(18)O_(54)(简称BST)微波介质陶瓷相组成、显微结构、烧结性能与介电性能的影响。结果表明:适量添加WO_3能通过不等价离子取代Ti位,产生晶格缺陷,促进离子扩散,不仅能有效降低BST陶瓷的烧结温度至1280℃,而且能减少氧空位的产生,降低介电损耗。同时适量WO_3时有新相BaWO_4生成,它的出现也有利于改善其介电性能。添加0.25wt%WO_3的BST陶瓷在1280℃烧结3 h时取得最佳介电性能:ε_r=80.4,Q·f=11740.85 GHz,τ_f=-23.3×10^(-6)/℃。

MnCO_3掺杂对Ba_4Sm_(9.33)Ti_(18)O_(54)微波介质陶瓷性能的影响

采用固相反应法,研究了MnCO_3掺杂对Ba_4Sm_(9.33)Ti_(18)O_(54)(简称BST)微波介质陶瓷结构与性能的影响。结果表明:适量掺杂MnCO_3,不仅可有效的降低BST陶瓷的烧结温度至1240℃,而且能通过Mn^(3+)+Ti^(3+)→Mn^(2+)+Ti^(4+)反应,抑制Ti^(4+)被还原及第二相Sm_2Ti_2O_7出现,改善其介电性能。当MnCO_3添加量为0.10wt%,在1240℃温度烧结3 h时,BST陶瓷获得最佳的介电性能:εr=83.64,Q·f=10007 GHz,τf=0.3×10^(-6)/℃。

Ba_4Nd_(9.33)Ti_(18)O_(54)微波介质陶瓷的微波合成及其低温烧结

采用微波加热合成了Ba4Nd9.33Ti18O54(BNT)微波介质固溶体陶瓷粉末,研究了微波加热工艺对BNT陶瓷相组成与微观形貌的影响。结果表明:微波加热相比于常规加热可以实现BNT陶瓷的低温快速合成;通过添加质量分数45%的B2O3-SiO2-CaO-MgO(BS)玻璃实现了BNT陶瓷于875℃烧结致密化。1 100℃微波合成的BNT陶瓷加BS玻璃烧结后具有最佳性能:εr=35.8,tanδ=12×10–4,σf=103.7 MPa,λ=2.576 W/(m.K)。

CuO-B_2O_3掺杂对Ba_4Sm_(9.33)Ti_(18)O_(54)陶瓷烧结性能及微波介电性能的影响

研究了CuO-B2O3助剂对Ba4Sm9.33Ti18O54陶瓷的烧结性能和介电性能的影响,结果表明:通过共添加CuOB2O3助剂(CB),陶瓷的烧结温度可以从1350℃降低到1050℃左右,当CB添加量达到10%时,产生第二相Ba2Cu(BO3)2,研究了CB的添加,对介电性能的影响,当CB的添加量为1wt%时,有以下微波介电性能ε=62.7,Q·f=4 270 GHz,τf=-11.1 ppm/℃。

Structure,defects,and microwave dielectric properties of Al-doped and Al/Nd co-doped Ba_(4)Nd_(9.33)Ti_(18)O_(54)ceramics

Low-loss tungsten–bronze microwave dielectric ceramics are dielectric materials with potential application value for miniaturized dielectric filters and antennas in the fifth-generation(5G)communication technology.In this work,a novel Al/Nd co-doping method of Ba_(4)Nd_(9.33)Ti_(18)O_(54)(BNT)ceramics with a chemical formula of Ba_(4)Nd_(9.33+z/3)Ti_(18−z)Al_(z)O_(54)(BNT–AN,0≤z≤2)was proposed to improve the dielectric properties through structural and defect modulation.Together with Al-doped ceramics(Ba_(4)Nd_(9.33)Ti_(18−z)Al_(4z/3)O_(54),BNT–A,0≤z≤2)for comparison,the ceramics were prepared by a solid state method.It is found that Al/Nd co-doping method has a significant effect on improving the dielectric properties compared with Al doping.As the doping amount z increased,the relative dielectric constant(εr)and the temperature coefficient of resonant frequency(τf)of the ceramics decreased,and the Q×f values of the ceramics obviously increased when z≤1.5.Excellent microwave dielectric properties ofεr=72.2,Q×f=16,480 GHz,andτf=+14.3 ppm/℃were achieved in BNT–AN ceramics with z=1.25.Raman spectroscopy and thermally stimulated depolarization current(TSDC)technique were firstly combined to analyze the structures and defects in microwave dielectric ceramics.It is shown that the improvement on Q×f values was originated from the decrease in the strength of the A-site cation vibration and the concentration of oxygen vacancies(VO××),demonstrating the effect and mechanism underlying for structural and defect modulation on the performance improvement of microwave dielectric ceramics.