冷冻-凝胶成形法制备定向通孔氧化铝陶瓷

由叔丁醇、氧化铝、丙烯酰胺组成的20%(体积分数,下同)陶瓷浆料,在温度梯度的诱导下,用冷冻-凝胶成形法制备了具有定向通孔结构的氧化铝陶瓷坯体。经过烧结后,制备出了高孔隙率、高强度的定向通孔陶瓷,50%气孔率的陶瓷体具有110MPa的轴向压缩强度。还研究了距离冷端不同位置孔隙的孔径、开孔率变化规律。

利用发泡-冷冻-凝胶法制备三维互联等级大孔SiC

采用发泡-冷冻-凝胶法制备出具有三维互联大孔径的多孔SiC陶瓷材料(HMS),利用XRD、SEM和CT-Scan研究了HMS的物相、显微组织、孔径分布和气孔率,并研究了PVA与SiC的质量比和表面活性剂(AES)含量对材料的影响。结果表明:HMS由单一的SiC相组成;材料具有三维互联大孔结构,孔径由三个级别的气孔组成;当PVA与SiC的质量比为1和2时制得的HMS孔径分布较均匀;AES含量为1.6%(质量分数)时,大孔SiC材料的孔隙率为74%,抗压强度为2.6 MPa。

溶胶-凝胶-冷冻法制备纳米TiO2及其表征

为解决纳米TiO2粉体易产生团聚的问题,采用溶胶-凝胶与冷冻干燥法制备纳米TiO2粉体.通过X射线衍射、扫描电子显微镜和紫外分光光度计对纳米TiO2粉体的物相组成、形貌和光催化活性进行了表征.实验结果表明:在400℃下所制得的TiO2纳米粉体的粒径约为6 nm,且粒度分布均匀,呈球形;所制得的TiO2纳米粉体在投加量为2 g/L时可使质量浓度为20 mg/L的甲基橙溶液在2.5 h内几乎全部降解.溶胶-凝胶与冷冻干燥法再结合阶段升温焙烧法可得到分散性好、粒径小和光催化活性好的粉体.

凝胶-冷冻法制备红薯微孔淀粉工艺的研究

以红薯淀粉为原材料制备红薯微孔淀粉,以红薯微孔淀粉的吸水率和吸油率为指标,探讨并优化凝胶–冷冻法制备红薯微孔淀粉的工艺参数。结果表明,制备红薯微孔淀粉的优化工艺参数为:红薯淀粉乳浓度100g/L、糊化时间40min、冷冻时间39h、糊化温度90℃,此工艺下制备的红薯微孔淀粉吸水率为467.51%、吸油率为76.36%。

柠檬酸应用于凝胶-冷冻法制备微孔淀粉的研究

为提高微孔淀粉的吸附性能,将柠檬酸用于凝胶-冷冻法制备红薯微孔淀粉,通过单因素试验和正交试验优化红薯微孔淀粉制备工艺。结果表明,红薯微孔淀粉制备的最佳工艺为:柠檬酸添加量3%、淀粉乳浓度100 g·L-1、糊化时间30 min、冷藏时间48 h、冷冻时间42 h。在此工艺参数条件下,制得的红薯微孔淀粉吸水率为277.32%、吸油率为68.61%。

凝胶辅助发泡法制备三维互联多孔SiC陶瓷

通过机械搅拌发泡结合冷冻-凝胶法制备了三维互联多孔SiC陶瓷材料,所获得的多孔陶瓷材料孔径分布均匀、孔结构可调并具有双级孔结构。研究了PVA含量与搅拌速度对多孔陶瓷孔结构及性能的影响。结果表明,随着PVA含量的增加,孔结构均匀程度和联通性提高、一级孔孔径尺寸逐渐减小且孔壁变薄。当ω(PVA)/ω(SiC)质量比为1.5时,样品孔径分布最均匀;并且随着搅拌速度的增大,孔隙率增加、联通性增强、一级孔孔径尺寸减小。当转速为1600 r/min时,SiC多孔陶瓷的孔隙率和抗压强度分别为88.42%和4.36 MPa。

Nanocomposite LiFePO_4·Li_3V_2(PO_4)_3/C synthesized by freeze-drying assisted sol-gel method and its magnetic and electrochemical properties

Nano-sized LiFePO_4·Li_3V_2（PO_4）_3/C was synthesized via a sol-gel route combining with freeze-drying. X-ray diffraction results show that this composite mainly consists of olivine Li Fe PO4 and monoclinic Li3 V2（PO4）3 phases with small amounts of V-doped LiFePO_4 and Fe-doped Li_3V_2（PO_4）_3. The magnetic properties of LiFePO_4·Li_3V_2（PO_4）_3/C are significantly different from LiFePO_4/C. Trace quantities of ferromagnetic impurities and Fe_2P are verified in LiFePO_4/C and LiFePO_4·Li_3V_2（PO_4）_3/C by magnetic tests, respectively. LiFePO_4·Li_3 V_2（PO_4）_3/C possesses relatively better rate capacities and cyclic stabilities, especially at high charge-discharge rates.The initial discharge capacities are 136.4 and 130.0 mA h g^（-1）,and the capacity retentions are more than 98% after 100 cycles at 2C and 5C, respectively, remarkably better than those of LiFePO_4/C. The excellent electrochemical performances are ascribed to the mutual doping of V^（3＋）and Fe^（2＋）, complementary advantages of LiFePO_4 and Li_3V_2（PO_4）_3 phases, the residual high-ordered carbon and Fe_2P with outstanding electric conductivity in the nanocomposite.