低温放电等离子烧结法制备氮化硅陶瓷

分别以MgO-Al2O3或MgO-AlPO4作为烧结助剂,采用放电等离子体低温快速烧结方法制备了主相为α相的Si3N4陶瓷材料.采用X射线衍射和扫描电子显微镜分析了样品的物相组成和显微结构;研究了烧结助剂及其含量、烧结温度对陶瓷样品的相对密度与力学性能的影响.结果表明:当采用4%质量分数,下同)MgO-4%Al2O3烧...     

不同烧结助剂制备的Si_3N_4陶瓷的氧化行为

以α-Si3N4粉末为原料,分别以Y2O3-La2O3和Y2O3-CeO2为烧结助剂,利用热压烧结法制备了Si3N4陶瓷。研究了Si3N4陶瓷样品在空气中高温下的氧化行为。结果表明:原始的α-Si3N4在烧结过程中完全转化为β-Si3N4。在1000～1350℃氧化100h后,用Y2O3-La2O3烧结助剂制备的样品表现为质量增加趋势,质量变化小于0.389mg/cm2,其氧化过程符合抛物线规律。用Y2O3-CeO2烧结助剂制备的样品,在1000℃氧化后表现为质量减小,为-0.248mg/cm2;在1230℃和1350℃表现为质量增加,分别为0.024mg/cm2和0.219mg/cm2,并且其氧化过程不符合抛物线规律。样品的氧化过程主要受2个扩散过程的控制,即稀土元素的向外扩散与氧的向内扩散。     

β-氮化硅陶瓷烧结致密化的研究

以β-Si3N4粉末为原料,MgAl2O4为烧结助剂,通过气氛压力烧结(GPS)制备出致密的β-氮化硅陶瓷材料,探讨了β-氮化硅陶瓷烧结机制,系统研究了烧结助剂质量分数、烧结温度以及保温时间对材料致密化的影响.     

氮化硅陶瓷的低温常压烧结及其力学性能

本文采用氧化镁(MgO)和磷酸铝(AlPO4)为烧结助剂,利用常压烧结工艺于1600℃制备了以α相为主相的氮化硅( Si3N4)陶瓷材料.利用XRD和SEM等对其物相组成和显微结构进行了表征,并分析烧结助剂含量对材料致密度的影响,研究氮化硅陶瓷的致密度与其力学性能之间的关系.结果表明:当AlPO4含量为20wt％ ～ 30wt％时,氮化硅陶瓷的致密度可达90％以上,抗弯强度为250～320 MPa.AlPO4在Si3N4陶瓷烧结中对提高其致密度与力学性能起到了重要的作用.     

ZrO2陶瓷的微波烧结制备及其性能

以微波热解制备的氧化锆粉体为原料、氧化钇为烧结助剂,采用微波烧结方式制备氧化锆陶瓷,研究了不同氧化钇含量对氧化锆陶瓷的微波烧结行为、物相组成、显微结构及致密化的影响。结果表明:在微波烧结过程中,随着Y_2O_3含量的增加,ZrO_2陶瓷的物相从m-ZrO_2逐渐转变为m-ZrO_2与t-ZrO_2(c-ZrO_2)并存,且ZrO_2陶瓷的晶粒随着烧结助剂含量的增加而逐渐变小,样品致密度下降。当烧结温度为1 450℃时,微波烧结获得的未添加烧结助剂的样品致密度达到99%,远远高于传统电阻烧结所获得样品的致密度。     

α-Si_3N_4与γ-Si_3N_4、α-Si_3N_4混合粉体超高压烧结的比较研究

以Y2O3-Al2O3-La2O3体系作烧结助剂,在5.4～5.7GPa、1620K～1770K的高温高压条件下进行了α-Si3N2与γ-Si3N4、α-Si3N4粉体的烧结研究.探讨了烧结温度及压力对烧结体性能的影响.实验测试结果表明:α-Si3N4、γ-Si3N4完全相变为β-Si3N4,相同的烧结条件下,α-Si3N4比γ-Si3N4、α-Si3N4混合粉体烧结试样的相对密度、维氏硬度高.α-Si3N4与γ-Si3N4、α-Si3N4混合粉体烧结试样的最高相对密度与维氏硬度分别为98.78%、21.87GPa和98.71%、21.76GPa.烧结体由相互交错的长柱状β-Si3N4晶粒组成,显微结构均匀.     

烧结工艺对β-氮化硅陶瓷的影响

以β-Si3N4粉末为原料,以YAG（钇铝石榴石）为烧结助剂,通过气氛压力烧结（GPS）制备出致密的β-氮化硅陶瓷材料,形成大小均匀的柱状颗粒和小球状颗粒复合显微结构,研究了烧结助剂质量分数、烧结温度以及保温时间对β-氮化硅陶瓷致密化程度及力学性能的影响.     

放电等离子体烧结Si_3N_4-BN复合陶瓷性能研究

以Si3N4和BN粉末为原料,Si3N4-BN复合粉末中BN的体积分数分别选定为10%、20%和30%,采用质量分数为2%的Al2O3和6%的Y2O3作为烧结助剂,分别在1500、1600和1650℃,压力50 MPa,保温5 min的条件下,采用放电等离子体烧结法制备了致密Si3N4-BN复合陶瓷。XRD结果和SEM分析表明:当煅烧温度为1650℃时,复合陶瓷中的α-Si3N4已完全转变为β-Si3N4;BN的加入抑制了复合陶瓷中Si3N4晶粒的生长而使结构细化;复合陶瓷的维氏硬度和断裂韧性随BN含量的增加而逐渐降低。     

添加Y2O3-Al2O3烧结助剂的氮化硅陶瓷的超高压烧结

以Y2O3-Al2O3体系为烧结助剂,在5.4～5.7 GPa,1 570～1 770K的高温高压条件下进行了氮化硅陶瓷的超高压烧结研究.用X射线衍射及扫描电镜对烧结样品进行了分析和观察,探讨了烧结温度及压力对烧结的陶瓷样品性能的影响.结果表明:得到的氮化硅由相互交错的长柱状β-Si3N4晶粒组成,微观结构均匀,α-Si3N4完全转变为β-Si3N4.经5.7GPa,1 770K且保温15min的超高压烧结,样品的相对密度达99.0%,Rockwell硬度HRA为99,Vickers硬度HV达23.3GPa.     

低温无压烧结氮化硅陶瓷的相变及致密化研究

采用氧化铝（Al2 O3）和氧化钇（Y2 O3）为烧结助剂,利用无压烧结工艺在低温下制备氮化硅陶瓷材料。利用XRD和SEM等着重研究了无压烧结氮化硅陶瓷低温阶段时的物相组成及其致密化。结果表明：当添加剂含量为10％,烧结温度高于1430℃时,α→β相转变较快;当烧结温度达到1510℃时,α相全部转变为β相。     

Ferroelectric Ceramics in the PbMg1/3Nb2/3O3-PbCd1/3Nb2/3O3 System

Solid solutions (1-x)PbMg_1/3Nb_2/3O₃ + xPbCd_1/3Nb_2/3O₃ with x = 0-0.30 are investigated with purpose to work out a capacitor ceramics with good dielectric properties and low sintering temperature. It is found that the perovskite phase forms at sintering near to 980°C and begins to decompose at higher temperatures. When x grows from 0 to 0.30, the Curie temperature linearly grows from -10°C to +25°C, the dielectric permittivity ε_m in the Curie point T_C decreases from 18000 to 6800 and the phase transition becomes more diffused. The dielectric permittivity at room temperature is rather high and the temperature stability is improved. The system is of interest, because it can serve as a base for working out some ceramic materials for capacitors with low sintering temperature, which needs of no special atmosphere at burning.     

3-叠氮甲基-3-甲基氧丁环的合成

以三羟甲基乙烷与碳酸二乙酯为原料,经环化反应合成了3-羟甲基-3-甲基氧丁环(HMM O)。在低温下,HMM O与对甲苯磺酰氯反应生成3-磺酸酯甲基-3-甲基氧丁环(M TM O)。M TM O和叠氮化钠发生叠氮化反应形成叠氮单体3-叠氮甲基-3-甲基氧丁环(AMM O)。三步反应收率分别为76%,96%,85%。用核磁、红外、元素分析和DSC表征了化合物的结构与性能。结构鉴定表明为目标化合物AMM O。     

3-溴甲基-3-甲基氧杂环丁烷的合成

以2,2-二溴甲基丙醇（BBMP）为初始原料,通过与碱发生关环反应生成3-溴甲基-3-甲基氧杂环丁烷（BrMMO）。讨论了碱的种类和用量对BBMP关环产率的影响以及反应体系中碱的浓度、反应温度和反应时间对合成BrMMO产率的影响。通过实验确定的最佳工艺条件为：BBMP与NaOH摩尔比为1.0∶1.1,NaOH醇溶液的质量分数为12%,反应温度为78℃,反应时间为4h时,BrMMO产率为65%。最终产品经元素分析、IR和1HNMR检测确定为BrMMO。该试验工艺简单,原料易得,且溶剂便于回收、污染小。     

3-溴甲基-3-甲基氧杂环丁烷的合成

以2,2-二溴甲基丙醇(BBMP)为初始原料,通过与碱发生关环反应生成3-溴甲基-3-甲基氧杂环丁烷(BrMMO).讨论了碱的种类和用量对BBMP关环产率的影响以及反应体系中碱的浓度、反应温度和反应时间对合成BrMMO产率的影响.通过实验确定的最佳工艺条件为:BBMP与NaOH摩尔比为1.0∶1.1,NaOH醇溶液的质量分数为12%,反应温度为78℃,反应时间为4 h时,BrMMO产率为65%.最终产品经元素分析、IR和1HNMR检测确定为BrMMO.该试验工艺简单,原料易得,且溶剂便于回收、污染小.     

The Preparation and Crystal Structure of TlMnCl3, TlFeCl3, TlCoCl3 and TlNiCl3

The compounds TlMnCl₃, TlFeCl₃, TlCoCl₃ and TlNiCl₃ were prepared by heating T1C1 with the corresponding transition metal dichloride in an evacuated ampoule. Atomic positions were determined from powder photographs. All four compounds were found to be related to the perovskite type structure. TlMnCl₃ has a cubic structure, space group Pm3m, with a_o = 5.025 Å. The other three compounds are hexagonal, probable space group P6₃mc, with cell dimensions (in Å) a₀ = 6.976 and c₀ = 6.008 for the Fe compound, a₀ = 6.907 and c₀ = 5.981 for the Co compound and a₀ = 6.863 and c₀ = 5.881 for the Ni compound. The three hexagonal compounds are isomorphous. A measureable concentration of basal plane stacking faults was found to occur in TlFeCl₃ and also, to a lesser degree, in TlCoCl_3.     

Tunable color emission in LaScO3:Bi3+,Tb3+,Eu3+ phosphor

LaScO₃:xBi³⁺,yTb³⁺,zEu³⁺ (x = 0 − 0.04, y = 0 − 0.05, z = 0 − 0.05) phosphors were prepared via high-temperature solid-state reaction. Phase identification and crystal structures of the LaScO₃:xBi³⁺,yTb³⁺,zEu³⁺ phosphors were investigated by X-ray diffraction (XRD). Crystal structure of phosphors was analyzed by Rietveld refinement and transmission electron microscopy (TEM). The luminescent performance of these trichromatic phosphors is investigated by diffuse reflection spectra and photoluminescence. The phenomenon of energy transfer from Bi³⁺ and Tb³⁺ to Eu³⁺ in LaScO₃:xBi³⁺,yTb³⁺,zEu³⁺ phosphors was investigated. By changing the ratio of x, y, and z, trichromatic can be obtained in the LaScO₃ host, including red, green, and blue emission with peak centered at 613, 544, and 428 nm, respectively. Therefore, two kinds of white light-emitting phosphors were obtained, LaScO₃:0.02Bi³⁺,0.05Tb³⁺,zEu³⁺ and LaScO₃:0.02Bi³⁺,0.03Eu³⁺,yTb³⁺. The energy transfer was characterized by decay times of the LaScO₃:xBi³⁺, yTb³⁺, zEu³⁺ phosphors. Moreover absolute internal QY and CIE chromatic coordinates are shown. The potential optical thermometry application of LaScO₃:Bi³⁺,Eu³⁺ was based on the temperature sensitivity of the fluorescence intensity ratio (FIR). The maximum S_a and S_r are 0.118 K⁻¹ (at 473.15 K) and 0.795% K⁻¹ (at 448.15 K), respectively. Hence, the LaScO₃:Bi³⁺,Eu³⁺ phosphor is a good material for optical temperature sensing.     

2,2,3-三氯-3-苯基-3-(3-甲基苯甲酰基)丙腈的合成研究

以苯甲酰氯、四氯化碳、间甲基苯甲酰氰为原料,合成了标题化合物。重点考察了氰化过程中不同原料配比、反应温度、时间、溶剂和催化剂用量对收率的影响。实验结果表明,其最佳反应条件为:n(1,1,2-三氯-2-苯基乙烯)∶n(3-甲基苯甲酰氰)=1∶1.2,二氯甲烷为反应溶剂,3 mmol催化剂三乙胺,室温反应5 h,总收率达80.6%。     

Thermal analyses of poly(3-hydroxybutyrate), poly(3-hydroxybutyrate-co-3-hydroxyvalerate), and poly(3-hydroxybutyrate-co-3-hydroxyhexanoate)

Thermal analyses of poly(3-hydroxybutyrate) (PHB), poly(3-hydroxybutyrate-co-3-hydroxyvalerate) [P(HB–HV)], and poly(3-hydroxybutyrate-co-3-hydroxyhexanoate) [P(HB–HHx)] were made with thermogravimetry and differential scanning calorimetry (DSC). In the thermal degradation of PHB, the onset of weight loss occurred at the temperature (°C) given by T_o = 0.75B + 311, where B represents the heating rate (°C/min). The temperature at which the weight-loss rate was at a maximum was T_p = 0.91B + 320, and the temperature at which degradation was completed was T_f = 1.00B + 325. In the thermal degradation of P(HB–HV) (70:30), T_o = 0.96B + 308, T_p = 0.99B + 320, and T_f = 1.09B + 325. In the thermal degradation of P(HB–HHx) (85:15), T_o = 1.11B + 305, T_p = 1.10B + 319, and T_f = 1.16B + 325. The derivative thermogravimetry curves of PHB, P(HB–HV), and P(HB–HHx) confirmed only one weight-loss step change. The incorporation of 30 mol % 3-hydroxyvalerate (HV) and 15 mol % 3-hydroxyhexanoate (HHx) components into the polyester increased the various thermal temperatures T_o, T_p, and T_f relative to those of PHB by 3–12°C (measured at B = 40°C/min). DSC measurements showed that the incorporation of HV and HHx decreased the melting temperature relative to that of PHB by 70°C. © 2001 John Wiley & Sons, Inc. J Appl Polym Sci 82: 90–98, 2001