Effect of Bi_2O_3 Additive on the Microstructure and Dielectric Properties of BaTiO_3-Based Ceramics Sintered at Lower Temperature

High performance X8R dielectric ceramics were prepared by dopingBi2O3 to BaTiO3-based ceramics.The effect of small amounts（≤1.2 mol%） ofBi2O3 additive on the microstructure and dielectric properties of BaTiO3-based ceramics have been investigated.The Bi2O3 ,acting as a sintering additive,can effectively lower the sintering temperature of BaTiO3-based ceramics from 1300 to 1130 °C.The bulk density of BaTiO3-based ceramics increased and reached the maximum value with increasingBi2O3 content.The dielectric constant increased with increasingBi2O3 until it reached the maximum value with 0.8 mol%Bi2O3 additive,and the dielectric loss decreased with increasingBi2O3 content.Optimal dielectric properties of ε=2470,tanδ=0.011 and △ε/ε 25 ≤±9%（-55-150 °C） were obtained for the BaTiO3-based ceramics doped with 0.8 mol%Bi2O3 sintered at 1130 °C for 6 h.

Research of Lead-free Na_(0.5)Bi_(0.5)TiO_(3)-BaTiO_(3)System Piezoelectric Ceramics

To reduce the coercive field of Na_(0.5)Bi_(0.5)TiO_(3),Ba TiO_(3)were added as dopant materials.Then the(1-x)Na_(0.5)Bi_(0.5)TiO_(3)-xBaTiO_(3)ceramic samples were produced in solid synthetic way.The optimum preparation condition and piezoelectric properties of the samples were investigated.The XRD results show that the fabric transites from rhombohedral to tetragonal gradually with the substitution of the Ba^(2+).The morphotropic phase boundaries(MPB)exists in the composition range of 0.06.

Synergistically Toughening Effect of SiC Whiskers and Nanoparticles in Al_2O_3-based Composite Ceramic Cutting Tool Material

In recent decades, many additives with different characteristics have been applied to strengthen and toughen Al2O3-based ceramic cutting tool materials. Among them, SiC whiskers and SiC nanoparticles showed excellent performance in improving the material properties. While no attempts have been made to add SiC whiskers and SiC nanoparticles together into the ceramic matrix and the synergistically toughening effects of them have not been studied. An Al2O3-SiCw-SiC np advanced ceramic cutting tool material is fabricated by adding both one-dimensional SiC whiskers and zero-dimensional SiC nanoparticles into the Al2O3 matrix with an effective dispersing and mixing process. The composites with 25 vol% SiC whiskers and 25 vol% SiC nanoparticles alone are also investegated for comparison purposes. Results show that the Al2O3-SiCw-SiCnp composite with both 20 vo1% SiC whiskers and 5 vol% SiC nanoparticles additives have much improved mechanical properties. The flexural strength of Al2O3-SiCw-SiCnp is 730＋ 95 MPa and fracture toughness is 5.6 ± 0.6 MPa.m1/2. The toughening and strengthening mechanisms of SiC whiskers and nanoparticles are studied when they are added either individually or in combination. It is indicated that when SiC whiskers and nanoparticles are added together, the grains are further refined and homogenized, so that the microstructure and fracture mode ratio is modified. The SiC nanoparticles are found helpful to enhance the toughening effects of the SiC whiskers. The proposed research helps to enrich the types of ceramic cutting tool and is benefit to expand the application range of ceramic cutting tool.

海水-富盐空气对BaTiO_(3)及Ni-BaTiO_(3) MLCC介电性能的影响

将BaTiO_(3)陶瓷和82 nF的Ni-BaTiO_(3)MLCC放置在海水及富盐空气两种恶劣环境下,利用阻抗分析仪、SEM及EDS探究处理0、24、48、72 h后性能的变化规律及腐蚀机理。结果表明,放置在海水中,BaTiO_(3)陶瓷在不同时间低频(10^(2)~10^(3)Hz)相对介电常数与介电损耗增加,且增加幅度巨大,在24 h陶瓷表面产生明显的保护膜,而在富盐空气下的陶瓷,72 h内介电性能变化范围小,表面没有明显的保护膜产生,但具有一定的腐蚀痕迹。82 nF的MLCC放置在海水及富盐空气72 h内高频(10^(5)~10^(6)Hz)电容值及介电损耗变化明显,这由盐分浸入内部结晶所导致,但其表面同样没有保护膜产生,这可能与电容器表面的氧化物涂层有关。

BaTiO_(3)-Bi(Zn_(3/4)W_(1/4))O_(3)无铅弛豫铁电陶瓷的制备及其储能性能的研究

采用固相反应法制备了(1-x)BaTiO_(3-x)Bi(Zn_(3/4)W_(1/4))O_(3)[简称(1-x)BT-x BZW]无铅陶瓷电容器。X射线衍射结果表明,所制得的陶瓷均为钙钛矿结构,没有发现第二相的生成。随着BZW的引入使得BaTiO 3陶瓷的晶相结构由四方相转变为伪立方相。采用SEM观察样品的晶粒尺寸和陶瓷表面的致密度,并对晶粒尺寸进行统计分析,陶瓷的平均晶粒尺寸从x=0.05时的2.36μm逐渐增大到x=0.20时的5.93μm。根据P-E曲线(电滞回线)可以观察到,添加适当量的BZW是调节BT弛豫行为的有效方法,能够有效提高陶瓷的储能性能。当掺杂量为x=0.15时,陶瓷具有最佳的储能特性,0.85BT-0.15BZW陶瓷的储能密度W rec为1.14 J/cm^(3),储能效率η可达92.60%,同时具有优异的温度和频率稳定性。因此,(1-x)BT-x BZW陶瓷有望成为制造高稳定性的储能设备的潜在候选材料。

Gd^(3+)掺杂调控BiFeO_(3)-BaTiO_(3)高温无铅压电陶瓷的结构与性能

用于监测航空发动机、重型燃气轮机等重大技术装备高温部件振动状态的压电加速度传感器,需要一种高居里温度压电陶瓷作为敏感元件,而电子元器件的无铅化是环境保护的迫切要求。采用传统的固相反应法制备一种Gd/Mn共掺杂的BF-BT((0.67BiFeO_(3)-0.33Ba_(1-x)Gd_(x)TiO_(3))+0.5%(质量分数)MnO_(2),x=0~0.02)高温无铅压电陶瓷,并研究Gd^(3+)掺杂浓度(x)对BF-BT陶瓷的相组成、微观结构、压电性能、介电弛豫行为及交流阻抗特征的影响。结果表明:所有样品均为单一钙钛矿结构,三方相(R)和四方相(T)共存,且T相含量随x增加而增加;适量的Gd^(3+)(x<0.02)固溶进入钙钛矿点阵之中能够促进BF-BT陶瓷晶粒的生长。掺杂Gd^(3+)的样品表现出增强的弛豫相变行为,相变温度(T_m)随x的增加而减小,而介电弛豫程度(ΔT_(relax))随x的增加而增大。采用R-CPE等效电路模型对BF-BT陶瓷的高温复阻抗谱(Cole-Cole图)进行拟合分析,发现样品在高温下的交流阻抗主要来自晶界的贡献。并且随着Gd^(3+)掺杂浓度的提高,样品的介电弛豫激活能不断增大,证实Gd^(3+)取代Ba^(2+)减少了晶格中氧空位浓度的施主掺杂效应。综合来看,x=0.01的样品具有最优的电学性能:T_(C)=425℃,d_(33)=126 pC/N,k_(p)=25.9%,tanδ=0.059,有望作为一种合适的高温压电材料被应用。

多层陶瓷电容器BaTiO_(3)材料的研究前景与展望

本文从BaTiO_(3)基介质材料的设计出发,阐述了发展高体积效率和高电容MLCC的关键问题和最新进展。本文在简要介绍MLCC和介电材料的基础上,总结了目前开发高性能可靠的BaTiO_(3)基介电材料存在的问题,并阐述了形貌调控、化学改性和掺杂改性等提高介电性能的策略。最后,对MLCC的发展和未来应用进行了展望。

BaTiO_(3)基无铅陶瓷介电温度稳定性研究

通过固相合成法制备了xBi(Zn,Zr)O_(3)-(1-x)(Ba,Ca)(Ti,Zr)O_(3)(BCTZ-xBZZ,x=0,0.005,0.02,0.04,0.06)无铅陶瓷体系,结合X射线衍射(XRD)、扫描电镜(SEM)、介电等表征,探讨了Bi(Zn,Zr)O_(3)陶瓷体系对(Ba,Ca)(Ti,Zr)O_(3)陶瓷的晶相、微结构、介电以及其温度稳定性的影响。研究结果表明:当预烧温度高于850℃时BCTZ-xBZZ合成粉体已基本形成单一的钙钛矿结构。在较低的烧结温度(1200~1300℃)下BCTZ-xBZZ陶瓷可以很好地烧结。所有BCTZ-xBZZ陶瓷都具有纯钙钛矿相,与此同时,陶瓷体系晶相经历了从四方晶相向伪立方相过渡。Bi(Zn_(0.5)Zr_(0.5))O_(3)显著影响了(Ba,Ca)(Ti,Zr)O_(3)陶瓷体系相变温度:铁电相-铁电相(T_(FE)),铁电相-顺电相(T_(c))。并且陶瓷体系存在弛豫行为,在高温范围内,修正的居里外斯定律1/ε_(r)-1/ε_(r,m)=C(T-T_(m))^(α)可以很好地用来解释Bi(Zn_(0.5)Zr_(0.5))O_(3)-(Ba_(0.98)Ca_(0.02))(Ti_(0.95)Zr_(0.05))O_(3)陶瓷体系的介电弛豫性。这归因于在A位和B位中无序性离子的共同作用。此外,陶瓷体系0.96(Ba_(0.98)Ca_(0.02))(Ti_(0.95)Zr_(0.05))O_(3)-0.04Bi(Zn_(0.5)Zr_(0.5))O_(3)在-25~135℃温度范围中,具有较稳定的电容温度系数(大约在±15%)和低的介电损耗(<0.1)。这表明该陶瓷在电容器中具有潜在的应用。

层状结构第二相增强BiFeO_(3)-BaTiO_(3)陶瓷电阻率研究

BiFeO_(3)-BaTiO_(3)(BF-BT)陶瓷兼具高居里温度和优异的压电性能,在高温压电传感器和驱动器等部件具有广泛的应用前景。BF-BT陶瓷在高温环境下电阻率较低,易造成器件高温性能恶化甚至失效。因此,改善BF-BT陶瓷电阻性能是应用推广必须解决的关键问题。作为一种铁酸盐,其电阻率很难通过掺杂改性等常规方法进行改善。本研究在BF-BT陶瓷体系中发现一种电阻率异常升高的现象,并证实这与样品中的第二相Bi_(25)FeO_(40)有关。显微结构分析表明,该第二相具有一种特殊的层状周期性结构,其中每三排原子构成一个周期,而缺陷大多集中在其中一层原子当中。本研究采用传统固相法成功地制备出纯相的Bi_(25)FeO_(40),将其作为外添加剂加入到0.70BF-0.30BT组分中,使基体组分在300℃的电阻率从1.03 MΩ·cm提高到4.33 MΩ·cm。此外,COMSOL仿真模拟的结果证实,通过引入该第二相可以将0.67BF-0.33BT组分电阻率提高一个数量级。根据能量过滤效应,这种特殊的结构具有高能垒,可以阻碍载流子迁移,从而提高BF-BT陶瓷电阻率。本工作为改善BF-BT陶瓷电阻率提供了一种切实可行的方法。

BaTiO_(3)基正温度系数热敏陶瓷研究现状及应用

正温度系数(positive temperature coefficient,PTC)热敏陶瓷是一类关键电子功能陶瓷,因其优异的特性在加热元件、传感器、电路保护器、温度控制器、电器消磁等领域都有广泛的应用。BaTiO_(3)作为主体材料制备的正温度系数热敏电阻(positive temperature coefficient thermistor,PTCR)是目前用量较大的一类正温度系数元件,具有重要的研究意义。本文阐述了正温度系数热敏材料的分类及其优缺点,介绍了正温度系数效应、热敏机理及BaTiO_(3)基正温度系数材料的半导化原理,综述了BaTiO_(3)基正温度系数热敏陶瓷国内外研究现状,分析了移峰剂、施主掺杂、受主掺杂、烧结工艺等因素对BaTiO_(3)基正温度系数热敏陶瓷的影响,总结了正温度系数热敏元器件的应用原理及其在相关领域的应用,并对正温度系数热敏陶瓷的无铅化进行了展望。

磁控溅射制备取向性BaTiO_(3)薄膜及其性能研究

磁控溅射具有制备的薄膜纯度高、致密性好、均匀,膜-基结合牢固、工艺重复性好,适合制备取向性无机非金属薄膜等优点,在微电子领域具有广泛的应用前景。研究了BaTiO_(3)薄膜沉积过程中的氩氧比、溅射温度、溅射时间、溅射功率等参数对薄膜微观结构的影响。结果表明,以取向性SrTiO_(3)为基底,当氩氧比为3∶1,基底温度为750℃,沉积时间为90 min,溅射功率为80 W时能够获得结晶较好、表面光滑、界面平整,厚度约为177 nm的(100)取向性BaTiO_(3)薄膜。通过优化工艺参数可以提高薄膜的质量和性能,为利用磁控溅射技术制备性能优异的压电薄膜奠定了基础。

Ultrahigh electrostrain with excellent fatigue resistance in textured Nb^(5+)-doped(Bi_(0.5)Na_(0.5))TiO3-based piezoceramics

(Bi_(0.5)Na_(0.5))TiO_(3)(BNT)-based lead-free piezoceramics exhibit excellent electric field-induced strain(electrostrain)properties,but often suffer from large hysteresis and poor fatigue resistance,which strongly limit their applications.Here,<00l>textured Nb5+-doped 0.8(Bi_(0.5)Na_(0.5))TiO_(3)–0.2(Bi_(0.5)K_(0.5))TiO_(3)(0.8BNT–0.2BKT)ceramics with a high degree of texturing(~80%)were prepared by the reactive template grain growth(RTGG)method using Bi4Ti3O12 as a template.By the combination of donor doping in the B-site and the RTGG method,the electrostrain performance achieves a significant enhancement.A high electrostrain of 0.65%and a piezoelectric coefficient(*33 d)of 1083 pm/V with reduced hysteresis at an electric field of 6 kV/mm are obtained.No electrostrain performance degradation is observed after unipolar electric field loading of 10^(5)cycles,showing excellent fatigue endurance.These results indicate that the texturing BNT-based lead-free piezoceramics by the RTGG method is a useful approach to developing eco-friendly actuators.

High energy storage properties in Ca_(0.7)La_(0.2)TiO_(3)-modified NaNbO_(3)-based lead-free antiferroelectric ceramics

In this work,(1−x)(0.92NaNbO_(3)-0.08BaTiO_(3))-xCa_(0.7)La_(0.2)TiO_(3)(NNBT-xCLT)ceramics were successfully designed and pre­pared by the solid-state reaction method.Investigations on the structure,dielectric,and energy storage properties were performed.The NNBT-0.25CLT ceramic with orthorhombic phase at room temperature was found to exhibit extremely small grain size and compacted microstructure.A large Wrec of 3.1 J/cm^(3) and a highηof 91.5%under the electric field of 360 kV/cm were achieved simultaneously in the sample.In addition,the energy storage performance of the sample exhibits thermal stability over the tem­perature range of 25-140°C and the frequency range of 5-500 Hz.The charge and discharge tests reveal that the ceramic shows a large current density CD of 965 A/cm2 and power density PD of 154 MW/cm^(3).This work demonstrates that the NNBT-0.25CLT ceramic is a prospective energy storage material for potential application in the field of pulsed power devices.

BaTiO_(3)陶瓷的低温冷烧结制备及性能研究

近年来,冷烧结低温制备陶瓷引起了很大关注,并在BaTiO_(3)陶瓷的制备上取得了一定进展。为了提高冷烧结BaTiO_(3)陶瓷性能,本研究采用水热法制备了分散性好、粒径为100 nm的四方相(晶格参数c/a为1.0085)BaTiO_(3)粉末。采用0.1 mol/L的乙酸在100℃/1 h的条件下对粉末进行水热活化处理。以质量分数10%Ba(OH)_(2)·8H_(2)O为熔剂,在350 MPa、400℃/1 h的条件下对粉体进行冷烧结,最后经600℃/0.5 h退火获得了相对密度为96.62%、晶粒尺寸为180 nm,常温介电(ε_(r))为2836,介电损耗(tanδ)低至0.03的BaTiO_(3)陶瓷。乙酸处理后高活性粉末表面形成的非晶钛层有效促进了陶瓷的致密化,抑制了杂相的生成和晶粒长大,提高了介电性能,大幅改善了冷烧结BaTiO_(3)陶瓷出现的介电弥散现象,从而实现了BaTiO_(3)陶瓷的低温冷烧结制备。

温度稳定型BaTiO_(3)基复合钙钛矿型介质材料研究进展

多层陶瓷电容器(MLCC)是最为重要的片式无源器件之一。随着电子系统应用领域逐渐拓展,MLCC被要求在更高工作温度和更宽温度范围内具有稳定的性能,因此迫切需要温度稳定型MLCC介质材料。BaTiO_(3)具有高介电常数、低介电损耗、价格低廉、环保无毒等优点,是最受关注的MLCC介质材料之一。但纯BaTiO_(3)难以满足温度稳定型MLCC对介质材料介温稳定性的要求,且因BaTiO_(3)居里温度的固有限制,单独对BaTiO_(3)改性通常难以提升其高温段的介温稳定性,无法满足X8R或X9R标准。因此,利用Bi(M)O_(3)、(Bi_(0.5)Na_(0.5))TiO_(3)、K_(0.5)Na_(0.5)NbO_(3)与CaCu_(3)Ti_(4)O_(12)等同样具有钙钛矿型结构的化合物与BaTiO_(3)形成固溶体,构建BaTiO_(3)基复合钙钛矿型介质材料,并在此基础上进一步掺杂改性,已成为获取温度稳定型介质材料的研究热点。本文主要综述了近年来温度稳定型BaTiO_(3)基复合钙钛矿型介质材料的研究进展,并对其发展前景进行了讨论。

(1-x)BaTiO_(3)-xCaCu_(3)Ti_(4)O_(12)复相陶瓷微观结构与介电性能研究

BaTiO_(3)作为强介铁电陶瓷在电容器领域发挥着巨大作用,提高其温度稳定性是目前急需解决的问题。采用CaCu_(3)Ti_(4)O_(12)来改善BaTiO_(3)(管筒称BT)的介电性能,提高其温度稳定性。通过传统固相法结合两步工艺制备了(1-x)BaTiO_(3)-x CaCu_(3)Ti_(4)O_(12)(BT-CCTO,x=0.05,0.1,0.15和0.2)复相陶瓷。结果表明,单相的BT和CCTO在1200℃部分发生反应,形成Ba_(4)Ti_(12)O_(27)和CaTiO_(3);且随着CCTO含量的增加,晶粒尺寸呈不均匀的晶粒生长方式,一组表现出四方(晶粒尺寸约1μm),另一组表现出长棒状(约10μm长),同时介电常数显著提升,且在100℃附近表现出弥散特性。

Microstructure regulation and failure mechanism study of BaTiO_(3)-based dielectrics for MLCC application

Most widely used dielectrics for MLCC are based on BaTiO_(3) composition which inevitably shows performance degradation during the application due to the migration of oxygen vacancies(V_(O)¨).Here,the BaTiO_(3),(Ba_(0.97)Ca_(0.03))TiO_(3),Ba(Ti_(0.98)Mg_(0.02))O_(3),(Ba_(0.97)Ca_(0.03))(Ti_(0.98)Mg_(0.02))O_(3),(Ba0.96Ca_(0.03)Dy0.01)(Ti_(0.98)Mg_(0.02))O_(3) ceramics(denoted as BT,BCT,BTM,BCTM and BCDTM,respectively)were prepared by a solid-state reaction method.The core-shell structured grains(~200 nm)featured with 10-20 nm wide shell were observed and contributed to the relatively flat dielectric constant-temperature spectra of BTM,BCTM and BCDTM ceramics.The TSDC study found that the single/mix doping of Ca^(2+),especially the Mg^(2+),Mg^(2+)/Ca^(2+)and Mg^(2+)/Ca^(2+)/Dy^(3+)could limit the emergence of V_(O)¨during the sintering and suppress its long-range migration under the electric-field.Because of this,the highly accelerated lifetimes of the ceramics were increased and the value of BCDTM is 377 times higher than that of BT ceramics.The p-n junction model was built to explain the correlation mechanism between the long-range migration of V_(O)¨and the significantly increased leakage current of BT-based dielectrics in the late stage of HALT.

增材制造钛酸钡压电陶瓷的高温烧结与极化工艺研究

为提高增材制造BaTiO_(3)压电陶瓷的综合性能,本文研究了BaTiO_(3)压电陶瓷的浆料剪切变稀特性及数字光处理(DLP)成型特性,揭示了DLP成型BaTiO_(3)压电陶瓷坯体在不同烧结温度条件下的致密化机制,探索了极化方向对DLP成型BaTiO_(3)陶瓷压电性能的影响规律。结果表明,调节高温烧结与极化工艺,可以在一定程度上改善DLP增材制造BaTiO_(3)压电陶瓷的电学性能。当烧结温度为1420℃、保温时间为2 h时,压电系数d_(33)最大,为163.4 pC/N,样品层间结合紧密,晶粒尺寸均匀。当Z轴与极化方向夹角由0°变为90°时,相对介电常数εr和d_(33)分别提高了29.37%和27.01%。当固含量为80%(质量分数)、烧结温度为1420℃、Z轴与极化方向夹角为90°时,样品d_(33)最大,达到182.4 pC/N。

High energy storage density and power density achieved simultaneously in NaNbO_(3)-based lead-free ceramics via antiferroelectricity enhancement

High-performance lead-free dielectric ceramics with simultaneously high energy storage density and power density are in high demanded for pulse power systems.To realize excellent energy-storage characteristics,a strategy to enhance antiferroelectricity and construct a local random field simultaneously was proposed in this study.Based on the above strategy,a series of(1-x)NaNbO_(3)-xBi(Ni_(1/2)Sn_(1/2))O3[xBNS,x=0.05,0.10,0.15,0.20,and 0.22]solid solutions were designed and fabricated.An ultrahigh energy storage density(Utotal)of 7.35 J/cm^(3),and recoverable energy density(Urec)of 5.00 J/cm^(3) were achieved in the 0.10BNS ceramics.In addition,an adequate stability of energy storage properties at a range of temperatures(20e140℃),frequencies(1e100 Hz),and fatigue test durations(1e1-10^(4) cycles)were realized in 0.10BNS ceramics.0.10BNS ceramics displayed a high current density of 1005 A/cm2,an ultrahigh power density of 100.5 MW/cm^(3,)and an ultrashort discharge time of 46.5 ns?This remarkable performance not only justified our strategy but also confirmed 0.10BNS ceramics as a promising candidate for energy storage.

Structure,dielectric properties of low-temperature-sintering BaTiO3-based glass–ceramics for energy storage

The 0.85BaTiO3–0.15Bi(Mg_(2/3)Nb_(1/3))O_(3)(BTBMN)ceramics with low-melting-temperature B_(2)O_(3)–Na_(2)B_(4)O_(7)–Na_(2)SiO_(3)(BNN)glass addition were prepared by the solid state method.The composition of the glass–ceramics was BTBMN–x wt.%BNN(x=0,1,3,5,7,9,12,15;abbreviated as BG).The sintering characteristics,phase structure,microstructure,dielectric properties and energy storage properties were systematically investigated.The sintering temperature of BTBMN ceramics was greatly reduced by the addition of BNN glass.The second-phase BaTi(BO_(3)T_(2)was observed in the BG system until the glass content reached 15 wt.%.The addition of BNN glass significantly reduces the grain size of BTBMN ceramics.With the increase of BNN glass content,dielectric constant of BG glass–ceramics at 1 kHz gradually decreased,the maximum dielectric constant("mT of BG glass–ceramics gradually decreased,while the temperature corresponding to the maximum dielectric constant(T_(m)T increased,the ferroelectric relaxation behavior decreased and the temperature stability of the dielectric constant gradually improved.As the BNN glass content increased,the breakdown electric field strength(BDS)of BG glass–ceramics increased first and then decreased,and the polarization values reduced gradually,while the trend of energy storage performance is similar to BDS.When the BNN glass content was 3 wt.%,the energy storage properties of the BG glass–ceramics were optimal,and a recoverable energy storage density(Wrec)of 1.26 J/cm^(3)and an energy storage efficiency(η)of 80.9%were obtained at the electric field strength of 220 kV/cm.The results showed that BG glass–ceramics were promising for energy storage capacitors.