含铁杂多酸盐Mossbauer谱研究 IV: 钼磷铁杂多酸盐的合成和Mossbauer谱

合成了钼磷铁杂多黄(NH4)4[PFeMo11O40H2]·9H2O和杂多蓝(NH4)4[PFeMo11O40H3]·11H2O的铵盐晶体, 用^5^7Fe同位素增丰Mossbauer谱法, 结合磁化率测定, 研究其结构与性质, 并讨论了四极分裂值Q2和Keggin结构杂多阴离子中MO6(M=Mo, Fe)八面体畸变大小的关系, 进一步证实Keggin结构杂多蓝阴离子中Mo(V)-O-Fe(III)间存在反磁交换作用。     

影响α-磷酸锆结晶度和生长形态的因素

采用HF络合法, 通过改进实验条件制得了α-磷酸锆(α-ZrP)微晶。讨论了HF/Zr比, P/Zr比, Zr浓度, 玻璃瓶质和反应温度等因素对α-ZrP结晶度和生长形态的影响。发现α-ZrP趋向于生成片状, 其片状最大外表面是α-ZrP的层板平面(001), 析晶速度的快慢影响该面的面积和厚度。d002, d110, d112衍射峰的相对衍射强度(XRD结果)与析晶速度有关并与晶体形状(SEM结果)存在着对应关系。     

K4H2[PMo9V3O40]·10H2O的合成及其晶体结构

采用低温技术,用X射线单晶衍射法测定了标题化合物的结构。晶体属P4/mnc空间群,=12.515(3),c=17.636(7)A,Z=2.用788个独立可观测反射精修所有结构参数得R=0.061.钼钒磷杂多酸阴离子中,PO4四面体是无序的,P-O键长1.54A.M(Mo,V)是6配位,M-O键长1.62-2.48A,K是7配位,K-O键长2.84-3.10A。     

预处理条件对Ni-Ce-P非晶态合金液相加氢活性的影响

采用真空骤冷技术制备了Ni82Ce0.31P17.7和Ni82P18非晶态合金。通过高压氢气中热处理, 使其粉化。DSC研究结果表明加入少量Ce使Ni-P非晶态合金晶化温度提高160℃。用高压反应釜考察了氧化温度和氢还原温度对Ni-De-P非晶态合金本乙烯液相加氢活性的影响, 并对比了Ni-P和Ni-Ce-P的加氢活性, 活性测试的结果表明: 氧化、还原处理过程使Ni-Ce-P加氢活性显著增加, 最佳的预处理条件是240℃氧化1h, 300℃氢气还原2h; Ni-Ce-P加氢活性是Ni-P加氢活性的3-4倍, 用AES和XPS研究了氧化、还原过程中,Ni-Ce-P表面性质的变化。     

化学修饰电极的研究XVIII,四苯基钴卟啉化学修饰玻碳电极的热处理及其对氧的催化还原

本文研究四苯基钴卟啉化学修饰玻碳电极的热处理,经热处理的这种电极[(PCo/GC)h]具有对氧催化还原的异常高的稳定性和活性.在纯O2饱和的0.05mol.L^-^1H2SO4溶液中经循环伏安(CV)扫描3000次(100mV/s),其催化活性未见明显降低.研究了热处理温度(500-1000℃)对(PCo/GC)h电极电催化性能的影响.用紫外可见光谱对热处理产物的结构进行了分析.用CV法及旋转圆盘电极研究了O2在(PCo/GC)h电极上电催化反应动力学,测定了速率常数.在该电极上O2的还原反应为二电子还原成H2O2的不可逆过程.     

Influence of interfacial reaction on interfacial performance of carbon fiber and polyarylacetylene resin composites

The influence of interfacial reaction on interfacial performance of carbon fiber/polyarylacetylene resin composites was studied. For this purpose, vinyltrimethoxysilane containing a double bond was grafted onto the carbon fiber surface to react with the triple bond of polyarylacetylene resin. The reaction between polyarylacetylene resin and vinyltrimethoxysilane was proved by reference to the model reaction between phenylacetylene and vinyltrimethoxysilane. Surface chemical analysis by XPS, surface energy determination from the dynamic contact angle, and the interfacial adhesion in composites was evaluated by interfacial shear strength test as well. It was found that vinyltrimethoxysilane, which can react with polyarylacetylene resin, had been grafted onto the carbon fiber surface. Furthermore, because the reaction between polyarylacetylene resin and vinyltrimethoxysilane took place at the interface, the interfacial adhesion in composites was significantly increased, and the improvement of interfacial adhesion was all attributed to the interfacial reaction.     

Interfacial Properties of Phosphate Glass Fiber/Poly(caprolactone) System Measured Using the Single Fiber Fragmentation Test

Phosphate glass fiber of the composition 20Na₂O–24MgO–16CaO–40P₂O₅ was produced using an in-house fiber drawing rig. The interfacial properties of the phosphate glass fiber/poly(caprolactone) (PCL) system were measured using the single fiber fragmentation test (SFFT). The system was calibrated using E-glass fibers and polypropylene system. This gave an interfacial shear strength (IFSS) of 4.1 MPa, which agrees well with other published data. The IFSS for the unsized (as drawn) phosphate glass fiber/PCL system was found to be 1.75 MPa. Fibers treated with 3-aminopropyl-triethoxy silane (APS) showed an IFSS of 3.82 MPa. X-ray photoelectron spectroscopic (XPS) analysis of unsized and silane sized fibers established the presence of silane on the fiber surface. Degradation tests of the silane treated fiber/PCL samples were carried out in deionised water at 37°C and it was found that the IFSS values decreased over time. Four others silanes were also investigated but APS gave the highest IFSS values.     

Preparation of Encapsulated Polymer Adhesion Beads and Adhesion with Porous Fibers

Adhesion beads of 10–130 μm, prepared by suspension polymerization, were encapsulated by melamine–formaldehyde. The capsule-type adhesives prepared consist of core and shell structure where the core region is sticky and viscous and the shell region consists of a hard shell at room temperature. The air permeable pads are made by hot pressing the mixture of capsule-type adhesives and porous materials including charcoal chips and Camellia sinensis fibers, which have a porous structure. The interfacial adhesion between polymer adhesion bead and porous fibers after processing shows a good porous sheet structure, which can penetrate air.     

Interfacial region in blends of linear polymers formed in situ

Blends of linear polyurethane and poly(methyl methacrylate) were obtained by the simultaneous curing of the mixture of two monomers. It was shown that the blends obtained in situ are two-phase systems in which two phases enriched in one of the blend components are separated by an intermediate region, the interphase. From the DSC data the compositions of two phases were estimated. It was observed that introduction of a filler leads to the appearance of an additional temperature transition lying between glass transition temperatures of the two phases. The fraction of the interphase was calculated from the calorimetric data. The introduction of a filler increases this fraction. This may be considered as some improving of compatibility of the two components in the presence of a filler.     

Reinforcement effects of multiwall carbon nanotubes in elastomeric matrices: Comparison with other types of fillers

Mechanical and electrical properties of composites based on butyl rubber and multiwall carbon nanotubes (MWNTs) are investigated. Gradual increases in elastic moduli are observed with the filler content. It was found that the degree of strain affects the electrical resistivity. Finally, the level of reinforcement imparted to a rubbery matrix by carbon nanotubes is compared with that provided by other types of fillers such as carbon black, clay fibers or layered silicates.