BNT-BKT-BiFeO3无铅压电陶瓷的压电性能和退极化温度

采用传统陶瓷制备方法,制备了系列新型无铅压电陶瓷材料(1-x-y)Bi0.5Na0.5TiO3-xBi0.5K0.5TiO3-yBiFeO3(简写为BNT-BKT-BF-x/y).研究了该体系陶瓷微观结构、压电性能和退极化温度变化规律.结果表明:在所研究的组成范围内,所制备的材料均能够形成纯钙钛矿固溶体,陶瓷三方、四方共存的准同型相界(MPB)成分为x=0.18～0.21,y=0～0.05,在准同型相界成分附近该体系陶瓷压电性能达到最大值:d33=171pC/N,kp=0.366.采用平面机电耦合系数kp和极化相位角θmax与温度的关系来确定退极化温度,得到的结果基本相同,陶瓷的退极化温度随BF含量的增加一直降低,随BKT含量的增加先降低后升高.     

(Na0.9K0.1)0.5Bi0.5TiO3-(Ba0.7Ca0.3)TiO3无铅压电陶瓷的结构与性能

采用固相法制备了(1-x)(Na0.9 K0.1)05Bi0.TiO3-xBa0.7Ca0.3 TiO3[(1-x)NKBT-xBCT]无铅压电陶瓷.研究了不同BCT含量(x=0,0.02,0.04,0.05,0.06,0.07)对NKBT陶瓷结构与电性能的影响.结果表明:所有样品均形成纯的钙钛矿结构,体系陶瓷的准同行相界(MPB)位于0.04≤x≤0.06.随着BCT掺量的增加,样品的退极化温度Td逐渐向低温方向移动,压电常数d33和平面机电耦合系数kp均先升高后降低.系列陶瓷电性能较佳:x=0.05时,kp最大,为0.29.当x=0.06时,样品的综合性能较好,其中d33=168 pC/N,kp=0.26,相对介电常数εr=1280,介质损耗tanδ =3.7;,剩余极化强度Pr=37 μC/cm2,矫顽场Ec =18.8 kV/cm.变温电滞回线和介电温谱表明体系陶瓷在Td以上可能存在极性相与非极性相共存.     

Sr和Nb复合掺杂Bi4Ti3O12基高温压电陶瓷的研究

采用传统固相法制备了Bi4Ti3O12 +0-91wt;Nb2O5+xwt; SrCO3(BTNO-Sr,0.00≤x≤1.50)层状压电陶瓷,研究了Sr掺杂对BTNO系陶瓷微观结构与电性能的影响.结果表明所有样品均为单一的铋层状结构相陶瓷.适量引入Sr能使BTNO系陶瓷的晶粒尺寸细化与均一,表现出介电弥散性,并改善其压电、机电和铁电性能.当x=0.50时,样品性能最佳:相对密度p=98.8;,压电常数d33=22 pC/N,平面机电耦合系数kp=9.5;,机械品质因子Qm =4462,剩余极化强度Pr=13.01μC/cm2,居里温度Tc=620℃.此外,介电性能和热稳定性能研究显示材料x=0.50具有好的压电稳定性,适合于制备高温高频压电器件.     

烧结温度和升温速率对Pb(Sb1/3Mn2/3)0.05Zr0.47Ti0.48O3压电陶瓷性能的影响

采用传统固相法制备了Pb(Sb1/3 Mn2/3)0.05Zr0.47Ti0.48 O3 (PMS-PZT)压电陶瓷.利用XRD、SEM和EDS等研究PMS-PZT陶瓷体系在烧结过程中形成的过渡液相和形成过渡液相温度(1100℃)附近的升温速率对陶瓷结构、压电和介电性能的影响.结果表明:不同烧结温度下,所有样品均为单一的钙钛矿四方相,过渡液相不会对相的结构有影响,但是当烧结温度较低时,过渡液相在烧结后期以玻璃相在晶界附近富集,对陶瓷的压电和介电性能有很大影响.随着烧结温度和升温速率的升高,PMS-PZT晶粒尺寸增大,晶粒均匀性和规则性得以改善,晶化质量得到提高;d33测试和阻抗分析测试结果表明PMS-PZT样品在1100℃附近以7 ℃·min-1升温速率并在1250℃烧结时具有最好的压电和介电性能:d33 =313 C/N,kp=0.59,Qm=1481,εr=1437,tanδ=0.53;.     

TGG法制备织构化K0.5Na0.5NbO3无铅压电陶瓷的性能研究

以熔盐法制备的K4Nb6O17片状粉体为前驱体,通过质子取代法制备了片状Nb2O5粉体,并且以其为模板结合模板晶粒生长(TGG)技术制备出较高织构度的X0.5Na0.5NbO3 (KNN)织构化无铅压电陶瓷,研究了不同工艺参数(模板含量、烧结温度和保温时间)对KNN织构化陶瓷的显微结构、介电性能以及压电性能的影响规律.研究结果表明:当模板含量、烧成温度和保温时间分别为10wt;,1120℃和5h时,可以获得织构度f为0.78的KNN织构化无铅压电陶瓷,并具有优异的压电和介电性能:平行于流延方向压电常数d33=141 pC/N,介电常数ε3T/ε0=503和平面机电耦合系数kp=39.7;;垂直于流延方向d33=112 pC/N,εT33/ε0=454和kp=37.5;.     

CaTiO3掺杂PbNb2O6高居里温度压电陶瓷的研究

采用传统电子陶瓷的制备方法,系统研究了(1-x)PbNb2O6-xCaTiO3(x=0、0.01、0.02、0.03、0.04)系高居里温度压电陶瓷.XRD分析表明,x=0时,材料只能形成三方非铁电相钨青铜结构,而x在0.01～0.04 mol范围内均能形成钨青铜型固溶体,利用XRD数据计算了晶体的晶格常数随x的变化,发现随着CaTiO3含量增加,晶胞体积减小.陶瓷材料的居里温度测试结果表明该体系具有高的居里温度(Tc＞400℃).测试了不同组成陶瓷的压电、介电性能,CaTiO3的掺杂量为x=0.03时陶瓷样品的压电常数达到d33=64pC/N,平面机电耦合系数kp=0.269,材料的介电常数ε33T/ε0=293,介质损耗tanδ=0.021,居里温度Tc=570℃,该组成具有优异的压电性能,适合于高温环境下的使用.     

Fe2O3掺杂(Ba0.7Ca0.3)TiO3-Ba(Zr0.2Ti0.8)O3无铅压电陶瓷的制备与性能

采用固相合成法制备了Fe2O3掺杂(Ba0.7Ca0.3)TiO3-Ba(Zr0.2Ti0.8)O3(简称BCZT)无铅压电陶瓷。借助XRD、SEM、阻抗分析仪等对该陶瓷的相组成、显微结构以及压电和介电性能进行了研究。结果表明,Fe2O3掺杂降低了BCZT无铅压电陶瓷的烧结温度并使居里温度Tc从85℃提高到95℃;当Fe2O3掺杂为0.02wt%～0.1wt%时,陶瓷样品均为ABO3型钙钛矿结构;少量Fe2O3掺杂促进了陶瓷晶粒的生长,但随着Fe2O3掺杂量进一步增加,陶瓷晶粒随之细化;当Fe2O3掺杂量为0.04wt%时,陶瓷样品具有最优综合电性能,其压电常数d33、机电耦合系数kp、机械品质因数Qm、介电损耗tanδ和介电常数εr分别为400 pC/N,0.40,51,0.023和3482。     

稀土掺杂Pb(Mg1/3Nb2/3)O3-PbTiO3压电陶瓷的烧结特性研究

在传统的固相反应制备工艺中,固相反应的烧结温度直接影响着陶瓷的物相结构、陶瓷致密度以及介电性能等.本文采用固相反应法制备x; Sm3掺杂PMN-PT压电陶瓷,通过控制不同的烧结温度,制备了一系列Sm-PMNPT陶瓷样品.利用X射线衍射仪、介电温谱以及准静态d33测量仪对陶瓷结构、介电性能、压电系数等性能进行表征.研究结果表明:烧结温度在1250℃,x=1.875mol;～2.5mol;,陶瓷样品的钙钛矿含量最大,压电系数最高可达1254 pC/N,kp=0.58,相对介电常数高达30000左右,密度达到8.48 g/cm3.     

Na0.5Bi0.5TiO3-K0.5Bi0.5TiO3-BaMnO3无铅压电陶瓷的结构与电性能

采用固相法制备了(0.8 -x)Na0.5 Bi0.5TiO3 -0.2K0.5Bi0.5TiO3-xBaMnO3(简称NBT-KBT-BM)无铅压电陶瓷,研究了不同BM含量(x=0,0.25％,0.50％,0.75％,1.00％,1.25％,物质的量分数)样品的物相组成、显微结构及电性能.结果表明:所制备的NBT-KBT-BM陶瓷样品均为单一的钙钛矿结构.与纯NBT-KBT陶瓷相比,掺BM陶瓷的烧结温度降低,相对密度ρr得到提高.随x的增加,材料的压电常数d33、平面机电耦合系数kp与机械品质因子Qm先增大后减小,而介电损耗tanδ以及退极化温度Td一直降低.BM的掺入降低了材料的矫顽场Ec,提高了剩余极化强度Pr,从而增强了铁电性.当x=0.75％时,陶瓷获得最佳性能:d33=167 pC/N,kp=0.269,Qm=133,εr=774,tanδ=2.93％.     

BiMnO_3改性BNT-BKT压电陶瓷的研究

为了提高BNT基压电陶瓷的电性能,采用传统的陶瓷制备方法,制备了一种Bi基的钙钛矿型无铅压电陶瓷 (1-x)Bi_(0.5)(Na_(0.82)K_(0.18))_(0.5)TiO_3-xBiMnO_3 (简写为BNKT-BMx).研究了Bi基铁电体BiMnO_3对该体系陶瓷微观结构和压电介电性能的影响.结果表明:在所研究的组成范围内陶瓷材料均能够形成纯钙钛矿固溶体,微量BiMnO_3不改变该体系陶瓷的晶体结构,但促进晶粒生长.随着BiMnO_3含量增加,低温介电反常峰消失,高温介电峰出现频率分散性.随BiMnO_3含量增加,压电常数d_(33)和机电耦合系数k_p先增加后降低,在x=0.01时,k_p=0.333,x=0.015时,d_(33)=170 pC/N,为该体系陶瓷压电性能的最优值.     

Modelling of mechanism of agglomeration of KCl crystallization

The article presents an analysis into agglomeration during KCl vacuum crystallization. The theoretical and experimental investigations into the mechanism of agglomeration during mass crystallization result in an extension of the growth phenomena within the known model equations. The basis for this is essentially constituted by the collision model concepts of the theory of floculation in disperse systems. The parameters derived from the microprocess analysis (energy dissipation, content of solids, growth rate of individual grains) lead to model equations which are confirmed by laboratory and test trials.     

Relationship of Morphological Types of Dynamic Forms of Crystals

Crystallography Reports - The relationship of morphological spectra (sets of data on the morphological types of real polyhedral crystals and their probabilities under current physicochemical...     

Velocities of Disappearance and Lifetime of Faces of Growing Crystals

The formulae for absolute R_disap and relative R velocities of disappearance and lifetime τ of faces of growing crystals have been derived for stationary growth. It was shown that the quantities are determined by the relative growth velocity R_A/R_critA of the vanishing face A with respect to the critical growth velocity R_critA and by the geometry of a crystal expressed by the trigonometric functions of interfacial angles β and γ formed between face A and the adjacent faces. R increases and τ decreases with the increase in R_A/R_critA to certain limiting values. The calculations have been verified and illustrated by the experimental results for triclinic potassium bichromate (KBC) crystals. Results enable ones to predict values of velocities of disappearance and lifetimes of undesirable, supplementary faces of any real crystal.     

Development of Pauling's concepts of geometric characteristics of atoms

The evolution of the geometric characteristics introduced by Pauling and their dependence on the specific features of the structure and chemical bonds have been considered. The values of the covalent and van der Waals radii are given as well as their relationships and mutual transitions.     

Dependence of the parameters of equations of viscous flow on chemical composition of silicate melts

The temperature dependence of viscosity of silicate melts is discussed in the framework of the Avramov–Milchev (AM) equation. The composition is described by means of two parameters: the molar fraction, x, and the “lubricant fraction”, l. The molar fraction is the sum of the molar parts x_i of all oxides dissolved in SiO₂, the molar fraction of the latter being 1 ? x. It is shown that, with sufficient precision, two of the parameters of the AM equation can be presented as unique functions of the molar fraction. On the other hand, x is not sufficient to determine properly the reference temperature T_r , at which viscosity is η_r = 10¹³ [dPa.s]. Therefore, additional parameter, “lubricant fraction” l, is introduced. For each of the components, l_i is a product of molar part x_i and a specific dimensionless coefficient 0 ≤ k_i ≤ 1 accounting for the specific contribution of this component to the increased mobility of the system. It is demonstrated that, for l > 0, the reference temperature is related to the “lubricant fraction” l through the reference temperature T_r,SiO2 of pure SiO₂.     

Comparative analysis of two methods of calculation of the orientation of domain walls in ferroelastics

Two types of domain-wall equations are analyzed: the equations derived by the Sapriel method and the equations obtained by interface matching of the thermal-expansion tensor. It is shown that, for W-type domain walls, these methods yield the same equations. For W′-type domain walls, the equations obtained by different methods coincide for proper ferroelastics and differ for improper ferroelastics.     

A review of measurement of thermophysical properties of silicon melt

Measurements of thermophysical properties of Si melt and supplementary study of X-ray scattering/diffraction by the authors' group were reviewed. The values obtained differed variously from those of literature. Density was 2–3% larger, surface tension 20–30% smaller, viscosity up to 40% larger, electrical conductivity 8% smaller, spectral emissivity more or less in good agreement with literature values, and thermal diffusivity a few percent larger. An anomalous density jump was found near the melting point. Surface tension and viscosity also showed anomaly. A strange time-dependent change of density was observed over 3 h after melting. X-ray analyses suggested a slight change in local atom ordering, but showed no sign of cluster formation. An addition of 0.1 at% gallium caused the density jump to disappear, while that of boron caused no change. An EXAFS study of the former melt indicated a strong interaction between Ga and Si atoms as if molecules of GaSi₃ existed. The implications of the measured properties are a possibility of soft-turbulence in an Si melt in a relatively large crucible, a more complicated manner of intake of oxygen depleted molten Si from the free surface region to underneath the growing crystal, and a relaxation of the melt after melting arising from trapped gas species.     

Generation of crystal structures of heteromolecular compounds by the method of discrete modeling of packings

Within the method of discrete modeling of packings, an algorithm of generation of possible crystal structures of heteromolecular compounds containing two or three molecules in the primitive unit cell, one of which has an arbitrary shape and the other (two others) has a shape close to spherical, is proposed. On the basis of this algorithm, a software package for personal computers is developed. This package has been approved for a number of compounds, investigated previously by X-ray diffraction analysis. The results of generation of structures of five compounds—four organic salts (with one or two spherical anions) and one solvate—are represented.