La3+,Ce4+对制备堇青石材料晶相转变及烧结性能的影响

以菱镁矿风化石、工业氧化铝和二氧化硅微粉为原料,加入不同含量氧化镧、氧化铈添加剂,通过固相反应合成制备堇青石材料。用XRD法和SEM法表征试样中的晶相组成和显微结构,用X’Pert Plus软件计算主晶相的晶格常数、晶胞体积和试样的相对结晶度,用半定量法计算试样中各晶相含量,用Scherrer公式计算主晶相的粒径大小。研究分析了La3+,Ce4+对制备堇青石材料晶相组成、主晶相粒径大小、晶胞常数、试样相对结晶度、显微结构及烧结性能的影响。结果表明:氧化镧比氧化铈具有更好的助堇青石烧结性,加入氧化镧的堇青石试样具有更好的致密性;随着氧化镧、氧化铈加入量的增加,堇青石晶胞常数和晶胞体积呈现先增大后减小趋势;Ce4+更高的电场强度促进了堇青石材料更容易发生晶相转变形成莫来石。     

菱镁矿风化石与叶腊石合成堇青石的结构表征

采用菱镁矿风化石、叶腊石、二氧化硅微粉为主要原料,研究分析烧成温度对合成堇青石结晶度、晶粒尺寸、晶相组成和显微结构来确定适宜的合成温度。用X′ Pert plus软件对X射线衍射图进行拟合,分析试样的结晶度,用半定量(semi-quantification)法对试样结晶相中晶相组成进行计算,用Scherrer公式计算试样中堇青石、方石英晶粒的粒径大小。结果表明：采用菱镁矿风化石与叶腊石为原料合成堇青石,当温度由1 350 ℃增加到1 400 ℃,试样的结晶度增加,堇青石晶粒尺寸和堇青石相量增加,在1 400 ℃时,试样结晶度最高,晶粒尺寸最大。晶相组成中堇青石相占67%,方石英相占33%。当温度大于1 400 ℃,试样结晶度降低,堇青石和方石英晶粒尺寸减小,当温度在1 500 ℃时,堇青石相消失,促进了方石英相析出。采用菱镁矿风化石与叶腊石为原料合成堇青石的最佳烧成温度为1 400 ℃。     

硅灰粉尘添加量对莫来石-堇青石复相材料晶相结构与性能影响

采用XRD和SEM法确定莫来石-堇青石复相材料的晶相结构及其含量。探讨不同含量硅灰粉尘对复相材料的晶相结构与性能的影响。实验结果表明:复相材料中存在α-堇青石、β-堇青石、μ-堇青石和莫来石四种晶相。堇青石含量随着硅灰粉尘结合剂含量的增加而增加。莫来石含量随着结剂含量的增加而减少。根据结构上的分析结果,确定2#为最隹的配方,其堇青石和莫来石含量分别为66.0%和33.7%,抗折强度为27.69Mpa,1次和10次热震抗折强度保持率分别为63.36%和33.7%,体积密度为2.69 g/cm3.     

稻壳一步法制备堇青石-莫来石多孔陶瓷

以稻壳、Al_2O_3和MgO为主要原料,按偏镁铝方案确定堇青石的组成,并以堇青石与莫来石质量比为7∶3进行配料,再掺少量Nd_2O_3为烧结助剂,用一步法烧成了堇青石-莫来石多孔陶瓷。测定了烧结试样的抗弯强度、显气孔率、热膨胀系数,用XRD分析了试样在烧结过程中的物相组成变化,并用SEM观察其显微结构。研究结果表明:在掺2%Nd_2O_3,1380℃保温5h条件下,制备的多孔陶瓷的抗弯强度为20.55MPa,显气孔率48.34%,热膨胀系数3.5×10~(-6)·℃-1,其主晶相为堇青石和莫来石,SEM显示晶体间存在大量孔隙。     

CaO杂质对铝型材厂工业污泥合成堇青石材料晶相结构及其含量影响

探讨原料组成对铝型材厂工业污泥合成堇青石材料的影响是非常重要的。研究目的有助于确定不同杂质在原料中允许的存在量,为选择其他原料提供可靠的依据。采用XRD法和SEM法分析各试样的晶相结构:用半定量分析方法确定各晶相的含量:用philipsX抪ertplus软件确定试样中各晶相结构参数。实验结果表明:CaO杂质含量从1.2~2.5%对合成堇青石有利:从2.5~2.8%堇青石含量开始下降:确定2.5%为CaO杂质最佳存在量,其对应的堇青石含量为91%。经plus软件确定结果:CaO杂质含量为1.2%时,其结构与单晶相同,晶胞参数变化很小:CaO含量从1.2~2.8%,其晶系由六方转变为四方结构,晶胞参数发生较大变化。镁铝尖晶石结构与晶胞参数变化较大,由单晶的立方结构转变为四方结构。     

反应温度与时间对铝型材厂工业污泥合成堇青石材料的得率与晶相结构影响

本研究主要探讨反应温度和反应时间对铝型材厂工业污泥合成堇青石材料的得率和晶相结构的影响。该污泥系由铝型材表面处理时产生的大量废液, 经沉淀过滤所得。主要成分是一种超细的γ-AlOOH, 其中部分是晶体, 部分是无定形体, 活性很高, 有利于堇青石晶相的形成, 能降低反应温度。 实验结果表明: 堇青石含量随着反应温度升高而增加; 晶相结构和晶胞参数与反应温度有关; 确定1350℃为最佳的反应温度; 反应时间在 2~5 h的试样中,堇青石含量增加, 在5~6 h含量降低. 5 h为最佳的反应时间。     

蜂窝状堇青石载体Al2O3涂层的原位合成

 采用改进的原位合成法（原位－浸涂法）在蜂窝状堇青石载体表面制备了多孔氧化铝涂层．着重研究了制备条件对涂层负载、晶相及其孔结构性质的影响，并与其他方法制备的涂层进行了比较．结果表明，采用多次原位合成法制备能提高氧化铝涂层的牢固度，但每次负载量偏低；原位－浸涂法适宜的制备参数为：水解温度83℃，水／异丙醇铝摩尔比60，pH值3．5～4．0，焙烧温度500℃．原位－浸涂法有利于制备Al2O3涂层，具有较好的牢固度，而且涂层的孔径分布窄，具有较大的比表面积、比孔体积和平均孔径．     

利用铝废渣制备片状堇青石的影响因素研究

以铝厂废渣、高岭土、滑石为主要原料,采用固相法合成片状堇青石。分析了原料种类、原料配方、烧结温度、保温时间和晶核剂对合成堇青石的影响,并通过XRD、SEM进行表征。结果表明,原料的纯度越高合成的堇青石纯度越高;富含镁的配方能完全形成堇青石相;最佳烧成温度为1 380℃,保温时间为4 h,此时得到的堇青石纯度最高,且呈现片状结构,颗粒大小均匀;堇青石熟料可以起到晶核剂的作用,促进堇青石的生成。     

蜂窝状堇青石载体A12O3涂层的原位合成

采用改进的原位合成法(原位-浸涂法)在蜂窝状堇青石载体表面制备了多孔氧化铝涂层．着重研究了制备条件对涂层负载、晶相及其孔结构性质的影响，并与其他方法制备的涂层进行了比较．结果表明，采用多次原位合成法制备能提高氧化铝涂层的牢固度，但每次负载量偏低；原位-浸涂法适宜的制备参数为：水解温度83℃，水／异丙醇铝摩尔比60，pH值3．5～4．0，焙烧温度500℃．原位-浸涂法有利于制备A12O3涂层，具有较好的牢固度，而且涂层的孔径分布窄，具有较大的比表面积、比孔体积和平均孔径．     

ZnO掺杂堇青石基红外陶瓷粉体的研制与表征

采用固相烧结法制备了ZnO替代MgO掺杂的堇青石基红外陶瓷粉体,通过红外辐射率测试、X射线衍射、热分析和红外吸收光谱等分析与表征,探讨了烧成温度、ZnO的掺杂量对其红外辐射率的影响.结果表明,在烧成温度为1 380 ℃、ZnO的掺杂量为22.5%(物质的量分数)时,所获得的堇青石基红外陶瓷粉体为单一相晶体,结晶完全,红外辐射率达0.978;适量地掺杂ZnO替代MgO,可在结构中使Zn2+代替Mg2+,引起堇青石结构中的非对称性,从而提高堇青石的红外吸收能力和辐射能力.     

Surface stabilized nanosized Ce(x)Zr(1-x)O(2) solid solutions over SiO(2): characterization by XRD, Raman, and HREM techniques

Ce(x)Zr(1)(-)(x)O(2) solid solutions deposited over silica surface were investigated by X-ray diffraction (XRD), Raman spectroscopy (RS), and high-resolution transmission electron microscopy (HREM) techniques in order to understand the role of silica support and the temperature stability of these composite oxides. For the purpose of comparison, an unsupported Ce(x)Zr(1)(-)(x)O(2) was also synthesized and subjected to characterization by various techniques. The Ce(x)Zr(1)(-)(x)O(2)/SiO(2) (CZ/S) (1:1:2 mole ratio based on oxides) was synthesized by depositing Ce(x)Zr(1)(-)(x)O(2) solid solution over a colloidal SiO(2) support by a deposition precipitation method and unsupported Ce(x)Zr(1)(-)(x)O(2) (CZ) (1:1 mole ratio based on oxides) was prepared by a coprecipitation procedure, and the obtained catalysts were subjected to thermal treatments from 773 to 1073 K. The XRD measurements disclose the presence of cubic phases with the composition Ce(0.75)Zr(0.25)O(2) and Ce(0.6)Zr(0.4)O(2) in CZ samples, while CZ/S samples possess Ce(0.75)Zr(0.25)O(2), Ce(0.6)Zr(0.4)O(2), and Ce(0.5)Zr(0.5)O(2) in different proportions. The crystallinity of these phases increased with increasing calcination temperature. The cell a parameter estimations indicate contraction of ceria lattice due to the incorporation of zirconium cations into the CeO(2) unit cell. Raman measurements indicate the presence of oxygen vacancies, lattice defects, and displacement of oxygen ions from their normal lattice positions in both the series of samples. The HREM results reveal, in the case of CZ/S samples, a well-dispersed nanosized Ce-Zr-oxides over the surface of amorphous SiO(2). The structural features of these crystals as determined by digital diffraction analysis of experimental images reveal that the Ce-Zr-oxides are mainly in the cubic geometry and exhibit high thermal stability. Oxygen storage capacity measurements by a thermogravimetric method reveal a substantial enhancement in the oxygen vacancy concentration of CZ/S sample over the unsupported CZ sample.     

Researches on the Structure and Properties of Mullite Solid Solution Made from Industrial Waste

1 INTRODUCTION The mullite has excellent properties of high tem- perature thermodynamics and mechanics, such as corrosion resistance, creep resistance, thermal shock resistance and high hot strength at high temperature. So it can be used as the inner lining of industrial furnace, thermal insulator material, crucible, protec- ting tube and electronic packaging material, which are widely used in such industries as metallurgy, ceramics, cement, and fireproof materials[1]. So far there has no …     

Influence of Fe_2O_3 Impurity on the Crystalline Structure of Cordierite Synthesized from Waste Aluminum Slag

1 INTRODUCTION Aluminum waste slag from aluminum factories isused as the main material to produce cordierite re-fractory material. The slag’s main composition is γ-AlOOH, which will convert into α-Al2O3 [1] at hightemperature, thus the product’s refractoriness can beimproved. Cordierite has good thermal stability andcan be widely served as high quality refractory ma-terial, electron encapsulating material, catalyst carrier,foamed ceramics, etc.[2]. Compared with th…     

Optical spectroscopy of chromium(III) in glasses and glass-ceramics of the magnesium aluminium silicate system

The optical absorption and emission of Cr³⁺ in glasses and glass-ceramics of the magnesium aluminium silicate system are reported. Glasses and glass-ceramics of high optical quality can be easily synthesized in the XMgO·Al₂O₃·2.5SiO₂ system simply by varying X (0.5–2.0) without recourse to thermal treatment. Evidence that Cr³⁺ resides in both the crystalline and glass phase of the glass-ceramic is presented. Furthermore the crystalline phases are identified as Al₂O₃ and MgAl₂O₄, and the glass phases as mullite and cordierite.     

Influence of TiO_2 Mineralizer on the Crystalline Structure of Cordierite Synthesized from Aluminum Slag

By adding small amount of TiO2, aluminum slag could be used to synthesize cor-dierite, α-Al2O3, TiO2 and dehydrated talc could generate solid solution to accelerate the solid-state reaction to form cordierite. The experimental results show that the content of cordierite increases with the increase of TiO2 added. 3.0% of TiO2 is determined to be the best amount, because all crystalline substances are converted into cordierite at this content. Philips X‘pert plus software analysis shows that when the content of TiO2 is from 0 to 1.0%, cordierite has the same hexagonal structure as the single crystal and the lattice parameters change slightly; when the content of TiO2 is from 1.0 to 2.0%, the cordierite still keeps hexagonal structure but the lattice parameters change greatly; when the content of TiO2 is from 2.0 to 3.5%, the cordierite is converted from hexagonal into rhombic and the lattice parameters change accordingly.     

Characterization of Pr-CeO2 Nano-crystallites Prepared by Low-temperature Combustion & Hydrothermal Synthesis

Pr-CeO2 Nano-crystalline red pigments were prepared by low-temperature combustion with a later hydrothermal treatment using Ce(NO3)3·6H2O and Pr6O11 as raw materials. The phase composition, coloring mechanism and morphology of pigments were analyzed by XRD, SEM,EDS and XPS. Results showed that Pr-CeO2 solid solution with a fluorite structure was obtained by the diffusion of Pr+3 into CeO2 crystal lattice during the synthesis process. XPS analysis indicated that Pr+3 substitutes Ce+4 in CeO2 and is compensated by oxygen vacancies. Compared with low-temperature combustion synthesis, the Pr-CeO2 pigments prepared with a subsequent hydrothermal treatment have an average grain size of about 16.70 nm, and the crystallinity and red tonality are improved.     

Structural characterization and oxidative dehydrogenation activity of V2O5/Ce(x)Zr(1-x)O2/SiO2 catalysts

The thermal stability of a nanosized Ce(x)Zr(1-x)O2 solid solution on a silica surface and the dispersion behavior of V2O5 over Ce(x)Zr(1-x)O2/SiO2 have been investigated using XRD, Raman spectroscopy, XPS, HREM, and BET surface area techniques. Oxidative dehydrogenation of ethylbenzene to styrene was performed as a test reaction to assess the usefulness of the VOx/Ce(x)Zr(1-x)O2/SiO2 catalyst. Ce(x)Zr(1-x)O2/SiO2 (1:1:2 mol ratio based on oxides) was synthesized through a soft-chemical route from ultrahigh dilute solutions by adopting a deposition coprecipitation technique. A theoretical monolayer equivalent to 10 wt % V2O5 was impregnated over the calcined Ce(x)Zr(1-x)O2/SiO2 sample (773 K) by an aqueous wet impregnation technique. The prepared V2O5/Ce(x)Zr(1-x)O2/SiO2 sample was subjected to thermal treatments from 773 to 1073 K. The XRD measurements indicate the presence of cubic Ce0.75Zr0.25O2 in the case of Ce(x)Zr(1-x)O2/SiO2, while cubic Ce0.5Zr0.5O2 and tetragonal Ce0.16Zr0.84O2 in the case of V2O5/Ce(x)Zr(1-x)O2/SiO2 when calcined at various temperatures. Dispersed vanadium oxide induces more incorporation of zirconium into the ceria lattice, thereby decreasing its lattice size and also accelerating the crystallization of Ce-Zr-O solid solutions at higher calcination temperatures. Further, it interacts selectively with the ceria portion of the composite oxide to form CeVO4. The RS measurements provide good evidence about the dispersed form of vanadium oxide and the CeVO4 compound. The HREM studies show the presence of small Ce-Zr-oxide particles of approximately 5 nm size over the surface of amorphous silica and corroborate with the results obtained from other techniques. The catalytic activity studies reveal the ability of vanadium oxide supported on Ce(x)Zr(1-x)O2/SiO2 to efficiently catalyze the ODH of ethylbenzene at normal atmospheric pressure. The remarkable ability of Ce(x)Zr(1-x)O2 to prevent the deactivation of supported vanadium oxide leading to stable activity in the time-on-stream experiments and high selectivity to styrene are other important observations.     

喷雾-胶凝法制备超细莫来石粉末

以水玻璃和硝酸铝为原料 ,通过喷雾 -胶凝法和共沸蒸馏技术制备莫来石前驱粉体 ,然后煅烧得到超细莫来石粉末 .用TG -DTA、XRD、TEM及BET研究了莫来石前驱粉体在煅烧过程中的热学性质、物相与比表面变化及颗粒大小与形貌变化 ,并对所制得的莫来石粉进行了表征 .结果表明 ,莫来石前驱粉体经 130 0℃煅烧 1h可制得粒径为 2 5nm～ 4 0nm ,比表面积为 4 2 5m2 /g的莫来石超细粉 ;煅烧过程中的物相变化次序为 :勃姆石 +非晶态SiO2 →非晶态Al2 O3 +非晶态SiO2 →γ -Al2 O3 +非晶态SiO2 → 3Al2 O3 ·2SiO2 .     

23Na, 29Si, and 13C MAS NMR investigation of glass-forming reactions between Na2CO3 and SiO2

The glass-forming reactions between sodium carbonate (Na2CO3) and silica (SiO2) have been investigated by 23Na, 29Si, and 13C magic-angle spinning (MAS) NMR spectroscopy. The multinuclear MAS NMR approach identifies and quantifies reaction products and intermediates, both glassy and crystalline. A series of powdered batches of initial composition Na2CO3.xSiO2 (x = 1, 2) corresponding to a sodium metasilicate (Na2SiO3) and sodium disilicate (Na2Si2O5) stoichiometry were investigated after periods of isothermal and nonisothermal heat treatments at different temperatures. Analysis of the 23Na quadrupolar coupling parameters has identified the early reaction product in all cases as crystalline Na2SiO3. In the nonisothermal experiment, this reaction is preceded by an early silica-rich melt phase formed around 850 degrees C. The early reactions are controlled by solid-state Na+ diffusion across the reaction zone in the grain interface layer. Crystalline Na2SiO3 precipitates in the interface layer, increasing its thickness between the Na2CO3 and the SiO2 grains and slowing down the rate of Na+ migration. This creates a secondary phase, which is temperature dependent. At low temperatures, where Na+ migration is impaired, the production of Na2SiO3 ceases and silica-richer phases are precipitated. In the case of the sodium disilicate batch, where excess SiO2 is present, a secondary reaction of Na2SiO3 with SiO2 forming a glassy phase is observed. A transient carbon-bearing phase has been identified by 13C NMR as a NaCO3- complex loosely bound to bridging oxygens in the silicate network at the SiO2 grain surface.