催化裂解CH4制备碳纳米管的影响因素

以柠檬酸法制备的Fe-MgO、Co-MgO和Ni-MgO为催化剂,CH4为碳源气,H2为还原气,在873、973和1073 K制备出碳纳米管,通过TEM和拉曼光谱表征,讨论了催化剂、制备温度、反应时间等因素对碳纳米管形貌、产率和内部结构的影响.结果表明:不同的催化剂在相同的温度下制备的碳纳米管的形态和内部结构有很大的差异.其中Fe-MgO催化剂制备的碳纳米管管径粗,且大小不均匀,而Ni-MgO催化剂制备的碳纳米管管径较细、较均匀.碳纳米管的产率随着裂解温度的变化而改变.Fe-MgO催化剂制备碳纳米管的产率随制备温度的升高而提高,而Ni-MgO催化剂制备碳纳米管的产率随制备温度的升高而降低.Fe-MgO催化剂制备碳纳米管,在1073K甚至更高的制备温度才能达到其最高产率.Co-MgO催化剂制备碳纳米管的产率在973 K左右产率较高,而用Ni-MgO催化剂制备碳纳米管,则在873 K甚至更低的制备温度就能达到最高产率.反应时间与碳纳米管的产率不成正比,有一最佳反应时间,如Ni-MgO催化剂的最佳反应时间为2 h.     

PEMFC膜电极组件(MEA)制备方法的评述

膜电极组件(MEA)是质子交换膜燃料电池的核心部件.本文在简述MEA结构的基础上,根据MEA制备过程中催化层支撑体不同,将目前已有的多种MEA制备方法分为两类制备模式:以GDL为支撑体和以PEM为支撑体的制备模式.文中对这些制备方法的特点进行了详细评述,对MEA制备方法的发展趋势进行了展望,认为以PEM为支撑体的制备模式是今后MEA制备的主要发展方向.     

聚碱式氯化铝制备实验探索

通过改进的制备方案,在常温下成功制备聚碱式氯化铝。无论在制备方法上还是在净水效果上,改进后的聚碱式氯化铝的制备方案都优于现有教材采用的实验方案。     

石墨烯晶圆的制备：从高品质到规模化

石墨烯晶圆是引领未来的战略材料,在集成电路、微机电系统和传感器等领域具有广阔的应用前景。实现石墨烯晶圆广泛应用的前提是高品质材料的规模化制备。可控性高、工艺兼容性强、成本低的化学气相沉积(chemical vapor deposition,CVD)法,是高品质石墨烯晶圆规模化制备的首选方法。本文将综述石墨烯晶圆的CVD制备进展：首先探讨石墨烯晶圆的制备需求,从实用牵引和应用场景出发,提出石墨烯晶圆的制备品质等级;随后重点介绍石墨烯的晶圆级制备方法和石墨烯晶圆材料的规模化制备技术;最后,对石墨烯晶圆可行的制备路线进行总结,并展望未来可能的发展方向。     

基于电迁移的蛋白质制备技术和方法新进展

基于电迁移的蛋白质制备技术是对一类分离和制备技术的统称,其特征是在电场的作用下对目标物质进行分离和纯化制备,这种技术在生物大分子和蛋白质组的研究中应用广泛。基于电迁移的制备技术主要包括制备型电泳、制备型电色谱、制备型等电聚焦和自由流电泳等。本文对每种制备型电迁移装置的设计、特点和基于该种装置的各种应用方法的优缺点进行了详细阐述,并列举了一些实例。另外,微量级制备型电泳因分离度高、回收率高以及高效快速的优点,在微量级生物样本分析中发挥着日益重要的作用,近年来备受关注,本文也着重关注了这方面的进展,并对基于电迁移的制备技术做了展望。     

改进的微乳液聚合制备的聚甲基丙烯酸甲酯的力学和光学性能研究

研究了改进的微乳液聚合方法制备的聚甲基丙烯酸甲酯(PMMA)的力学和光学性能, 并与本体聚合制备的PMMA相比较. 研究结果表明, 由改进的微乳液聚合制备的PMMA具有较高的Tg和富间规度, 在较宽的温度范围内具有较高的力学模量. 此外, 它的拉伸强度、拉伸模量及断裂伸长率均比本体聚合制备的PMMA样品高. PMMA的折光率与制备方法关系不大, 但由改进的微乳液聚合制备的PMMA样品消光系数更小, 更加透明. 这说明由改进的微乳液聚合方法制备的PMMA具有更广泛的应用前景.     

《制备色谱技术及应用》(第二版)

(ISBN 978-7-122-11958-2)该书从色谱科学的角度详细地阐述了制备色谱的原理、重要的实验技术、关键性色谱分离技巧及其应用。内容包括制备色谱的基础知识、制备薄层色谱、常压柱色谱、低压及中压柱色谱、高压制备液相色谱、高速逆流色谱、模拟移动床色谱、顶替色谱、制备气相色谱、电泳以及与制备色谱技术紧密相关的生物代谢产物的提取分离技术等。本书对制备色谱技术的系统介绍具有简明、系统、全面的特点。     

书刊征订

《制备色谱技术及应用》(第二版)(ISBN 978-7-122-11958-2)该书从色谱科学的角度详细地阐述了制备色谱的原理、重要的实验技术、关键性色谱分离技巧及其应用。内容包括制备色谱的基础知识、制备薄层色谱、常压柱色谱、低压及中压柱色谱、高压制备液相色谱、高速逆流色谱、模拟移动床色     

Cu/SiO2催化剂制备方法对其草酸二甲酯催化氢解性能的影响

以化学吸附水解法、蒸氨法和浸渍法制备了Cu/SiO2催化剂, 并用于草酸二甲酯氢解制备乙二醇的反应. 发现用化学吸附水解法制备的催化剂具有最高的催化活性和乙二醇选择性, 乙二醇得率可达92.6%. 对还原前后不同方法制备的催化剂进行表征发现, 浸渍法制备的催化剂中Cu物种不能很好地得到分散, 因此活性较差. 蒸氨法和化学吸附水解法能较好地分散Cu物种. 由于化学吸附水解法制备的催化剂的Cu0表面积较蒸氨法的大, 且Cu＋表面积相当, 故活性高于蒸氨法制备的催化剂.     

电化学技术制备纳米材料研究的新进展

利用电化学方法制备与组装纳米材料是近年来发展起来的一项新技术.本文对电化学方法在纳米材料制备中的应用及其研究进展做了较为全面的概述,着重介绍了模板电化学法合成纳米材料、稳定剂保护下电化学还原法制备金属溶胶、电化学台阶边缘修饰法制备一维纳米材料以及脉冲超声电化学法制备纳米粒子,并对其应用前景做了展望.     

Immobilization of Glucose Oxidase on Ordered Macroporous Silicas Functionalized with Amino Group

A novel glucose oxidase immobilized on three‐dimensionally ordered macroporous (3DOM) material has been prepared by firstly preparation of hybrid 3DOM SiO₂‐NH₂ materials using colloidal crystal method, and following covalent immobilization of glucose oxidase on the pore walls of the 3DOM materials. The materials were characterized by SEM, FTIR, DSC and BET techniques. SEM observation shows that the macropores are highly ordered and are interconnected by small windows. FTIR measurement shows that there are amino and organic groups in the pore walls. The surface area of the 3DOM SiO₂‐NH₂ material is about 10.2 m²/g. The loaded amount of enzyme is increased with amino content in the materials. The immobilized enzyme has high activity, thermal stability and can be reused.     

7种胺基键合硅胶的制备及其对重金属Pb2+的吸附

制备了氨丙基键合硅胶（SiO₂-N）、乙二胺-N-丙基键合硅胶（SiO₂-2N）、二乙烯三胺基键合硅胶（SiO₂-3N）、三乙烯四胺基键合硅胶（SiO₂-4N）、四乙烯五胺基键合硅胶（SiO₂-5N）、五乙烯六胺基键合硅胶（SiO₂-6N）和聚乙烯亚胺基键合硅胶（SiO₂-nN）,一步法制备的SiO₂-N和SiO₂-2N的胺基键合密度高达2.07 mmol/g和1.71mmol/g,两步法制备的SiO₂-nN的胺基键合密度为0.02mmol/g,其余胺基键合硅胶中胺基密度约为0.50mmol/g。这7种胺基键合硅胶被用于水溶液中常见重金属离子Pb²⁺的吸附研究。结果表明,在30℃条件下,分别加入10 mL 400 mg/L的Pb²⁺溶液（pH 5）和20 mg胺基键合硅胶进行吸附,10 h后,Pb²⁺吸附量达到最大,吸附过程符合Freundlich等温方程。SiO₂-N、SiO₂-2N、SiO₂-3N、SiO₂-4N、SiO₂-5N、SiO₂-6N和SiO₂-nN对Pb²⁺的吸附量依次为131.28、138.98、85.37、75.22、61.87、79.12和114.06 mg/g,这些胺基键合硅胶在吸附Pb²⁺方面均非常具有潜力。     

P123-PMMA dual-templating generation and unique physicochemical properties of three-dimensionally ordered macroporous iron oxides with nanovoids in the crystalline walls

Three-dimensionally (3D) ordered macroporous (3DOM) iron oxides with nanovoids in the rhombohedrally crystallized macroporous walls were fabricated by adopting the dual-templating [Pluronic P123 and poly(methyl methacrylate) (PMMA) colloidal microspheres] strategy with ferric nitrate as the metal precursor in an ethanol or ethylene glycol and methanol mixed solution and after calcination at 550 °C. The possible formation mechanisms of such architectured materials were discussed. The physicochemical properties of the materials were characterized by means of techniques such as XRD, TGA/DSC, FT-IR, BET, HRSEM, HRTEM/SAED, UV-vis, XPS, and H(2)-TPR. The catalytic properties of the materials were also examined using toluene oxidation as a probe reaction. It is shown that 3DOM-structured α-Fe(2)O(3) without nanovoids in the macroporous walls was formed in the absence of P123 during the fabrication process, whereas the dual-templating strategy gave rise to α-Fe(2)O(3) materials that possessed high-quality 3DOM structures with the presence of nanovoids in the polycrystalline macropore walls and higher surface areas (32-46 m(2)/g). The surfactant P123 played a key role in the generation of nanovoids within the walls of the 3DOM-architectured iron oxides. There was the presence of multivalent iron ions and adsorbed oxygen species on the surface of each sample, with the trivalent iron ion and oxygen adspecies concentrations being different from sample to sample. The dual-templating fabricated iron oxide samples exhibited much better low-temperature reducibility than the bulk counterpart. The copresence of a 3DOM-structured skeleton and nanovoids in the macropore walls gave rise to a drop in the band-gap energy of iron oxide. The higher oxygen adspecies amounts, larger surface areas, better low-temperature reducibility, and unique nanovoid-containing 3DOM structures of the iron oxide materials accounted for their excellent catalytic performance in the oxidation of toluene.     

聚乙烯亚胺改性聚丙烯腈中空膜固定脂肪酶

聚丙烯腈是富腈基的高分子聚合物,易修饰改性,广泛应用于膜分离应用.我们以聚丙烯腈中空膜为载体,采用化学法交联聚乙烯亚胺并固定脂肪酶,固定过程中引入海藻酸钠,用CaCl_2进行后处理,得到固定化脂肪酶PAN-PEI-SA/E-CaCl_2载酶量为31.70(mg enzyme)/(g support),酶活为50.20 U/(g support),15次重复使用可保留58.77%的酶活,与游离酶相比耐酸性和耐温性有所提高,相同条件下与Nov 435相比,酶活更高,这表明最终得到的固定化脂肪酶有良好的工业应用前景.     

Fabrication of Mesoporous SiO2@CaSiO3 Hollow Spheres as Carriers for pH-sensitive Drug Delivery

Hollow mesoporous silica(HM-SiO₂) was prepared by the improved stober method. On this basis, HM-SiO₂ was dispersed in an alkaline solution for surface etching. Meanwhile, calcium source was introduced to combine with on the surface to form a CaSiO₃shell layer and an unprecedent SiO₂@CaSiO₃sphere with a hollow double-shell structure was obtained. The as-synthesized SiO₂@CaSiO₃ was characterized by X-ray diffraction(XRD), scanning electron microscopy(SEM), transmission electron microscopy(TEM), N₂-BET, IR and UV-Vis techniques, and its sustained release capacity of doxorubicin(DOX) loading was investigated. The drug loading capacity can be achieved to 0.692 mg DOX/mg SiO₂@CaSiO₃, exhibiting pH-responsivity under low pH conditions.     

核壳硅碳复合微球固定相的制备及其在糖类分离中的应用

采用一步法在二氧化硅(SiO₂)表面涂覆酚醛树脂聚合物(PF),并在氮气气氛下碳化,制备了核壳硅碳复合微球(Sil@MC)固定相。实验对Sil@MC固定相进行形貌观察和孔结构分析,表明制备出的Sil@MC固定相具有良好的单分散性,包覆后的Sil@MC材料比表面积为302 m²/g,平均孔径为9.5 nm,孔容为0.63 cm³/g,说明通过共聚反应成功地将碳材料固定在二氧化硅上。将制备的Sil@MC材料作为HPLC固定相,采用匀浆法装柱,以乙腈-水(含0.1%(v/v)甲酸)作为流动相,发现Sil@MC色谱柱在高效液相色谱-质谱中可以实现4种极性糖类化合物(D-(+)-氨基葡萄糖盐酸盐、葡萄糖、D-(+)-海藻糖二水合物和棉子糖)的分离,然而未涂覆酚醛树脂的SiO₂材料未能对这4种极性糖类化合物实现分离。实验进一步对Sil@MC固定相的性能进行了评价,代表性的低聚糖异构体松三糖和棉子糖、耐斯糖和水苏糖及乳寡糖异构体3'-唾液酸乳糖和6'-唾液酸乳糖、乳-N-四糖和乳-N-新四糖在Sil@MC色谱柱中被成功分离,峰形良好,展现了基于酚醛树脂衍生碳的核壳硅碳复合材料在在极性化合物色谱分离方面具有应用潜力。     

醇脱氢酶在反胶束溶液中的催化动力学性质

以十六烷基三甲基溴化铵(CATB)-辛烷-己醇反胶束体系对醇脱氢酶(ADH)进行固定化,试验了含水量、酶液pH值、CTAB和己醇浓度对ADH固定化的影响。对游离酶和固定化酶的催化动力学性质研究表明：酶促反应的最适pH值分别为8.2和8.8,最适温度分别是31℃和20℃,对乙醇的米氏常数Km分别为12mmol/L和7.4mmol/L。在30℃时,游离酶存放150min后失活90%,固定化酶失活50%,表明反胶束固定化ADH有较好的热稳定性。     

Activity and lifetime of urease immobilized using layer-by-layer nano self-assembly on silicon microchannels

Urease has been immobilized and layered onto the walls of manufactured silicon microchannels. Enzyme immobilization was performed using layer-by-layer nano self-assembly. Alternating layers of oppositely charged polyelectrolytes, with enzyme layers “encased” between them, were deposited onto the walls of the silicon microchannels. The polycations used were polyethylenimine (PEI), polydiallyldimethylammonium (PDDA), and polyallylamine (PAH). The polyanions used were polystyrenesulfonate (PSS) and polyvinylsulfate (PVS). The activity of the immobilized enzyme was tested by pumping a 1 g/L urea solution through the microchannels at various flow rates. Effluent concentration was measured using an ultraviolet/visible spectrometer by monitoring the absorbance of a pH sensitive dye. The architecture of PEI/PSS/PEI/urease/PEI with single and multiple layers of enzyme demonstrated superior performance over the PDDA and PAH architectures. The precursor layer of PEI/PSS demonstrably improved the performance of the reactor. Conversion rates of 70% were achieved at a residence time of 26 s, on d 1 of operation, and >50% at 51 s, on d 15 with a six-layer PEI/urease architecture.     

Synthesis and electrochemical performance of hierarchical porous carbons with 3D open-cell structure based on nanosilica-embedded emulsion-templated polymerization

A novel synthesis of hierarchical porous carbons （HPCs）with 3D open-cell structure based on nanosilica- embedded emulsion-templated polymerization was reported. An oil-in-water emulsion containing SiO2 colloids was fabricated using liquid paraffin as an oil phase, resorcinol/formaldehyde and silica sol as an aqueous phase, and Span 80/Tween 80 as emulsifiers. HPCs with macropore cores, open meso/ macropore windows, and abundant micropores were synthesized by the polymerization and carbonization of the emulsion, followed by scaffold removal and further KOH activation. A typical HPCs sample as supercapacitor electrode shows the charge/discharge capability under large loading current density （30 A/g） coupling with a reasonable electrochemical capacitance in KOH electrolyte solution.     

Adsorption and hydrolytic activity of trypsin on a carboxylate-functionalized cation exchanger prepared from nanocellulose

Immobilization of enzymes on polymer supports has been considered as a powerful technique in biomedical applications. In this study, a cellulose-based hydrogel, poly(acrylic acid)-modified poly(glycidylmethacrylate)-grafted nanocellulose (PAPGNC) was synthesized by graft copolymerization technique and well characterized. A pancreatic serine protease trypsin (TRY) was immobilized onto PAPGNC, under different optimized conditions. The optimum pH for TRY adsorption was found to be 6.5, and the adsorption attained equilibrium within 90 min. The kinetic data were found to follow pseudo-first-order model, which is based on solid capacity. The well agreement of equilibrium data with Langmuir isotherm model confirms the monolayer coverage of TRY onto PAPGNC surface, and the maximum adsorption capacity was found to be 140.65 mg/g at 30 °C. The temperature dependence indicates an endothermic process. The relative activity of immobilized TRY in the hydrolysis of casein was higher than that of the free enzyme over broader temperature ranges. The immobilized TRY had high temperature and long-storage stability as compared to free TRY. Spent adsorbent was effectively degenerated using 0.1 M KSCN with the retention in catalytic activity of 87% even after four cycles. The present investigation shows that PAPGNC is a valuable polymer support for the recovery of TRY from aqueous solutions and subsequent casein hydrolysis.