MO.P2O5玻璃的结构与性能

主要介绍了质子导体ＭＯ．Ｐ２Ｏ５玻璃，从其结构、化学稳定性和导电原理等方面总结了前人所做的工作．ＭＯ．Ｐ２Ｏ５玻璃系统化学性较好，在其中注入Ｈ＾＋使某些成分的玻璃具有快质子导电率。对ＭＯ．Ｐ２Ｏ５系统进行深入研究，以寻找人真实用的玻璃，可望发展新型无机室温快质子导电电解质，为发展室温燃料电池打下良好基础。     

Alumina-coated hollow glass spheres/alumina composites

Coating of alumina onto the surface of hollow glass spheres was accomplished by controlled heterogeneous precipitation from aqueous solutions. The processing conditions were optimized to yield thin and uniform precursor coatings. After calcination, converting the precursor to alumina, the alumina-coated hollow glass spheres formed free-flowing powders that were used to produce glass/alumina composites with up to 35 vol% of controlled and well dispersed closed porosity. The dielectric constants and the flexural strengths of such porous composites were determined as a function of porosity. This revised version was published online in November 2006 with corrections to the Cover Date.     

Effects of TiO2/Al ratio on microstructures and mechanical properties of TiAl base composites

Effects of TiO₂/Al ratio on the microstructures and mechanical properties of in situ Al₂O₃/TiAl based composites were investigated. The results indicate that the as-sintered products consist of grains of nearly lamellar α₂ + γ structure with a dispersion of randomly oriented Al₂O₃ particles. A 43.9Ti-38.6Al-17.5TiO₂-nNb₂O₅ system was compared to 57.46Ti-36.78Al-5.76TiO₂-nNb₂O₅ system. The lamellar spacing of the products increases and the α₂ phase volume decreases with decreasing TiO₂/Al ratio. For each system, as the volume of α₂ phase increases, the average lamellar spacing decreases. Strength increases with an increasing TiO₂/Al ratio due to the amount of α₂ phase. Al₂O₃ phase increases with increasing TiO₂/Al ratio. Toughness increases with decreasing TiO₂/Al ratio. When the Nb₂O₅ content is smaller than 6 wt.%, the lamellar spacing plays an important role in toughness than the Al₂O₃ content. When the Nb₂O₅ content is larger than 6 wt.%, the Al₂O₃ content exhibits significantly increases the values of toughness than lamellar spacing.     

两种不同微结构的高硅氧/酚醛树脂基复合材料动态压缩性能研究

为获得高硅氧/酚醛树脂基复合材料动态压缩力学性能以及研究微结构对该种材料力学性能影响,利用分离式霍普金森压杆分别对两种不同微结构的高硅氧/酚醛树脂基复合材料进行动态压缩实验。实验结果发现,在相同应变率下,高硅氧丝/酚醛树脂基复合材料强度高于高硅氧布/酚醛树脂基复合材料。此外,实验结果还显示微结构对材料的失效模式有显著影响,高硅氧丝/酚醛树脂基复合材料显现出一种劈裂的失效模式,而高硅氧布/酚醛树脂基复合材料却发生剪切断裂。进一步通过对其断裂形貌分析指出,高硅氧玻璃纤维的排列方式决定复合材料的断裂模式。     

Mechanical properties and microstructures of co-precipitation derived tetragonal Y2O3-ZrO2-Al2O3 composites

Y-TZP Al₂O₃ specimens (2.5 mol% Y₂O₃-ZrO₂ and 5 to 30 wt% Al₂ 03) were prepared from coprecipitated powders and their mechanical properties were studied. The addition of alumina to Y-TZP improves the attainable density of the materials after sintering at 1500° C and reduces the degradation of their densities due to porosity formation when the materials are sintered above 1500° C. Near theoretical density could be achieved for most of the samples after HIPing at 1500° C for 1/2 h at 200 M Pa pressure. The fracture strength of the HIPed specimens was in the range 2.0 to 2.4 GPa and the stress intensity factor was in the range 3.5 to 6.0 MPa m^1/2. The mechanical strength of the materials was not degraded seriously after autoclaving in water at 175° C for 24 h. The surface layer of transformed monoclinic zirconia was less than 70 m thick even after autoclaving at 175° C for 5 days.     

Effect of addition of Ag on the microstructures and electrical properties of sol-gel derived SnO2 glass composites

The effect of addition of Ag on the microstructure and electrical properties of sol-gel derived SnO₂-glass composites was examined. Comparisons of the microstructures and electrical properties were carried out between glass composites prepared by a sol-gel method and a conventional one using glass frit. The glass composite gels and the SnO₂-glass powder mixtures containing AgNO₃ were calcined at 500 °C in order to decompose AgNO₃ into Ag and then fired at 900 °C. In the sol-gel derived glass composites, the grain growth of Ag was suppressed and Ag particles connected mutually at the boundaries of aggregated gel particles to form three-dimensional networks. Thus, the glass composite derived by the sol-gel method showed a high electrical conductivity and a positive temperature coefficient of resistance (TCR). The highly electrical conductive paths of Ag in the glass composite were effectively formed when powder compacts were formed at a higher pressure. On the other hand, in the glass composites prepared using SnO₂-glass powder mixtures, coarse-grained Ag particles were isolated in closed pores regardless of the forming pressure, and therefore did not contribute to electrical conduction in the glass composite.     

Sintering and technological properties of alumina/zirconia/nano-TiO2 ceramic composites

The present work focuses on studying the effect of nano TiO₂ (0.0–25 mass%) on the sintering behavior and mechanical properties of alumina/zirconia ceramic composites. Al₂O₃–ZrO₂–TiO₂ oxides mixture was sintered at 1600 °C to obtain the desired composites. The sinterability and the technological properties of these ceramic composites, i.e. the sintering parameters and microhardness as well as thermal shock resistance were investigated. Moreover, phase composition and microstructure of the sintered bodies were examined using X-ray diffraction (XRD), scanning electron microscopy (SEM) and energy dispersive spectrometer (EDS). The results revealed that nano TiO₂ is a beneficial component for alumina/zirconia ceramic composites. The batch containing 20 mass% TiO₂ exhibited the highest sintering and mechanical properties as well as resistance to thermal shock. The obtained microstructure exhibited high compacted ceramic matrix composites.     

Effects of TiO/Al ratio on microstructures and mechanical properties of TiAl base composites

Effects of TiO₂/Al ratio on the microstructures and mechanical properties of in situ Al₂O₃/TiAl based composites were investigated. The results indicate that the as-sintered products consist of grains of nearly lamellar ?₂ + ? structure with a dispersion of randomly oriented Al₂O₃ particles. A 43.9Ti-38.6Al-17.5TiO₂-nNb₂O₅ system was compared to 57.46Ti-36.78Al-5.76TiO₂-nNb₂O₅ system. The lamellar spacing of the products increases and the ?₂ phase volume decreases with decreasing TiO₂/Al ratio. For each system, as the volume of ?₂ phase increases, the average lamellar spacing decreases. Strength increases with an increasing TiO₂/Al ratio due to the amount of ?₂ phase. Al₂O₃ phase increases with increasing TiO₂/Al ratio. Toughness increases with decreasing TiO₂/Al ratio. When the Nb₂O₅ content is smaller than 6 wt.%, the lamellar spacing plays an important role in toughness than the Al₂O₃ content. When the Nb₂O₅ content is larger than 6 wt.%, the Al₂O₃ content exhibits significantly increases the values of toughness than lamellar spacing.     

Effects of TiO2 doping on microstructure and properties of directed laser deposition alumina/aluminum titanate composites

ABSTRACT

Al₂O₃-based composite ceramics have excellent high temperature performance and are ideal materials for preparing hot end components. However, poor fracture toughness and thermal shock resistance limit its applications. Based on the excellent low thermal expansion characteristics and thermal shock resistance of Al₂TiO₅ ceramic, different composition ratios of Al₂O₃/Al₂TiO₅ composite ceramics were prepared by directed laser deposition (DLD) technology. Effects of TiO₂ doping amount on microstructure and properties of the composite ceramics were investigated. Results show that α-Al₂O₃ phase is discretely distributed in the continuous aluminum titanate matrix when TiO₂ doping amount between 2 and 30?mol%. With the increase of TiO₂ doping amount, content of Al₂O₃ gradually decreases and its morphology changes from cellular to dendritic. When TiO₂ doping amount reaches 43.9?mol%, the microstructure transforms into fine Al₂TiO₅/Al₆Ti₂O₁₃ eutectic structure. Property test results show that Al₂O₃/Al₂TiO₅ composite ceramics have good comprehensive mechanical properties when TiO₂ doping amount between 2 and 6?mol%.     

湿热老化对玻璃纤维/环氧树脂复合材料性能的影响

为研究玻璃纤维(GF)/环氧树脂复合材料湿热老化机制, 首先, 利用称重法、动态热机械分析仪(DMA)、SEM和矢量网络介电分析仪研究了湿热老化对GF/环氧树脂608(EP608)复合材料性能的影响;然后, 分析了复合材料的吸湿率、力学性能、介电性能与老化时间的关系, 并对其老化机制进行了探讨。结果表明:随老化时间延长, GF/EP608复合材料的力学性能和介电性能均有不同程度的下降;湿热老化对GF/EP608复合材料吸湿率的影响符合Fickian扩散定律;树脂基体的塑化、水解和基体-纤维界面的破坏是造成GF/EP608复合材料力学性能和介电性能下降的主要因素。所得结论可为GF增强环氧树脂基复合材料的应用提供科学依据。      

Role of alumina in flexure of glass/epoxy composites

The influence of particulate additions of alumina on the flexural properties of glass-fabric/epoxy composites was studied. The additions improved translaminar flexural strength, while decreasing interlaminar strength. The translaminar bending modulus showed an increasing trend whereas its interlaminar value showed a decrease, up to additions of 3 vol%. The mechanisms of deformation and the fracture features have been discussed with the aid of scanning electron microscopy.     

镍掺杂方式对Al2O3／Ni复合材料的结构及力学性能的影响

分别以Ni包裹氧化铝微球、氧化铝包裹Ni微球以及氧化铝／Ni共沉淀复合微球粉体为烧结原料，通过热压烧结法制备了Ni质量含量在0％～30％的氧化铝基金属陶瓷。利用SEM，TEM，XRD对烧结Al2O3／Ni金属陶瓷的微结构及前躯体、热还原粉体和金属陶瓷的晶相进行了分析，通过阿基米德法测量了金属陶瓷的相对密度，并分别利用三点弯曲法和单边切口横梁法对材料的抗弯强度和断裂韧性进行了评估。结果显示：3种粉体制备的金属陶瓷分别形成了晶间型、晶内型及晶间／晶内混合型结构，且在烧结过程中，Ni相在某种程度上降低了材料的致密化速率，也抑制了氧化铝晶粒的长大．同时，Ni掺杂方式的不同导致了氧化铝基质的断裂模式及力学性能的变化。     

添加微量Ti元素对Diamond/Cu复合材料组织及性能的影响

分别采用在Cu基体添加0. 1 wt%的Ti 元素形成Cu₂Ti合金和在Diamond 颗粒表面镀钛(DiamondTi) 的方法, 制备了含Diamond 体积分数为60 %的Diamond/Cu₂Ti 复合材料和DiamondTi/Cu 复合材料。对比分析了Ti 元素对复合材料微观组织、界面结合及性能的影响规律。结果表明: 添加0. 1 wt%Ti 元素能改善Diamond与Cu 的界面结合, 在界面处观察到明显的碳化物反应层; 且以Cu₂Ti合金的方式添加Ti 元素改善界面的效果优于在Diamond 颗粒表面镀Ti 的方式。所制备的Diamond/Cu₂Ti 复合材料的热导率为621 W(m·K) - 1, 而DiamondTi/Cu复合材料的热导率仅为403. 5 W(m·K) -1, 但均高于未添加Ti 制备的Diamond/Cu 复合材料。      

玻璃纤维表面纳米SiO_2改性对GF/PCBT复合材料力学性能的影响

为研究玻璃纤维(GF)表面纳米SiO2改性对GF增强树脂基复合材料力学性能的影响,利用真空辅助模压(VAMP)工艺制备了不同含量的纳米SiO2表面改性GF增强聚环状对苯二甲酸丁二醇酯(PCBT)复合材料。分析了GF表面改性对GF/PCBT复合材料力学性能的影响,研究了纤维表面改性对GF/PCBT复合材料抗湿热老化性能的影响规律。纤维拔出试验结果表明:经表面处理的GF/PCBT复合材料的界面剪切强度提高了1.16倍;采用含量为0.5wt%和2wt%(与树脂质量比)的纳米SiO2处理GF表面后,复合材料的三点弯曲强度分别提高1.5倍和1.67倍,弯曲模量分别提高1.03倍和1.17倍。SEM结果显示:当纳米SiO2用量为2wt%时,破坏后的纤维表面被树脂完全覆盖,树脂与纤维粘结良好。在湿热条件下,由于纳米SiO2颗粒的存在,水分子很难通过界面相扩散到改性后的材料内部,其抗湿热性能提高。     

Photoluminescence of Ti3+ in P2O5-Na2O-Al2O3 glass

The optical properties (absorption and luminescence) of Ti³⁺ in a P₂O₅ Na₂O-Al₂O₃ glass have been studied in the temperature range 12 to 300 K. A very broad infrared emission band at 860 nm, has been observed for the first time in an inorganic glass, when excitation is performed in the Ti³⁺ absorption band (T_2g → E_g transition in cubic field approximation). The spectroscopic characteristics of this system are compared with those of the Ti³⁺ as a dopant in AL₂O₃ single crystals.