Effect of Hydration–Dehydration Processes on the Structure and Porosity of Detemplated Silica Fibers

A study was carried out on the conditions of template removal (calcination or extraction by solvents) and hydration–dehydration processes on the hexagonal structure and porosity of detemplated fibers. The hydration–dehydration cycle leads to a decrease in fiber porosity, especially in fiber detemplation by extraction with surfactant solvents such as ethanol and acetic acid.     

Characterization of Heterogeneous Catalysts by use of Test Reactions

The following report gives an overview on work done in the Catalysis Laboratory of the Department of Chemistry, National University of Singapore over the last 15 years (1989–2004). Much of this work can be described as “characterization of catalytically active surfaces through test reactions”. The methods, systems studied and the reactions that we evaluated will be described. The review will mostly concentrate on work from the authors’ laboratory, but other relevant work will also be cited.     

Nitrogen Adsorption Study of MCM-41 Molecular Sieves Synthesized Using Hydrothermal Restructuring

Nitrogen desorption scanning hysteresis loops (DSHLs) for large-pore MCM-41 silicas (pore diameter from 4.0 to 6.5 nm) are reported for the first time. DSHLs for MCM-41 were compared with those of conventional mesoporous silicas and no appreciable differences were found, although hysteresis loops and DSHLs for the latter were usually broader. Since desorption behavior of conventional porous silicas is appreciably influenced by pore connectivity, the observed similarity in hysteresis behavior suggests single-pore blocking effects for MCM-41 due to variation of pore diameter along its nonintersecting channels. It was also shown that the steepness of nitrogen desorption branches at relative pressures close to 0.4 often results from proximity of the lower pressure limit of adsorption-desorption irreversibility and consequently it is not justified to consider it as an indication of narrow pore size distribution. Thus, application of desorption data in calculations of pore size distributions may be grossly misleading.     

Metal-support interaction in mesoporous silica supported cobalt Fischer-Tropsch catalysts

Summary The pore structure of silica supports (SiO₂ or MCM-41) has little influence on the metal-support interaction in silica supported cobalt catalysts. Cobalt dispersion, reduction behavior, and catalytic properties for the Fischer-Tropsch synthesis were primarily affected by the metal particle size.     

Improving MCM‐41 as a Nitrosamines Trap through a One‐Pot Synthesis

Copper oxide was incorporated into MCM‐41 by a one‐pot synthesis under acidic conditions to prepare a new mesoporous nitrosamines trap for protection of the environment. The resulting composites were characterized by XRD, N₂ adsorption–desorption, and H₂ temperature‐programmed reduction techniques, and their adsorption capabilities were assessed in the gaseous adsorption of N‐nitrosopyrrolidine (NPYR). The adsorption isotherms were consistent with the Freundlich equation. The copper salt was deposited onto MCM‐41 during the evaporation stage and was fixed on the host in the calcination process that followed. MCM‐41 was able to capture NPYR in air below 373 K but not at 453 K. Loading of copper oxide on MCM‐41 greatly improved its adsorption capability at elevated temperatures. The influence of the incorporation of copper into MCM‐41 samples and the adsorption behavior of these samples are discussed in detail.     

Zr-MCM-41的合成及其表征

以Zr(NO3)4·3H2O为锆源，通过直接合成法得到了Zr-MCM-41介孔材料，考察了不同Zr/Si摩尔比对样品的影响，其中Zr/Si的摩尔比最大为0.25。随着Zr/Si的摩尔比的增加，2θ=2°附近的100晶面的衍射峰强度逐渐降低，当Zr/Si摩尔比大于0.25后得不到介孔Zr-MCM-41材料。对所得样品采用XRD、TG-DTA、N2吸附 脱附几种分析方法进行了表征。     

MoS2纳米管包覆单壁碳纳米管束的制备

MoS₂ nanotube coated SWNT (Single wall carbon nanotube) bundles have been successfully prepared by adsorbing (NH₄)₂MoS₄ onto SWNT bundles and subsequent heat treatment under H₂ at 900 ℃ in a tube furnace. The morphologies, structure and composition of the as-prepared sample were investigated by XRD, SEM, HRTEM coupled with EDS. The formation mechanism has also been preliminarily discussed.     

纯二氧化钛介孔分子筛的合成与表征

分别用不同链长的烷基磷酸酯和脂肪胺两类不同表面活性剂为模板剂合成了纯二氧化钛介孔分子筛（Ti-TMS1，Ti-TMS2），并用溶剂法代替高温焙烧法成功地脱除了模板剂。用 XRD、TEM等测试手段对这类材料的结构进行了表征，研究了反应条件对所制备样品的结构的影响。结果表明：得到的纯二氧化钛介孔分子筛为较规则的六角堆积排列，孔径为2.7～4.4 nm, 且其纳米孔径大小可以通过改变烷基磷酸酯模板剂的烷基链长而调节。此外还发现，采用的烷基磷酸酯模板剂的烷基链越长，制得的二氧化钛介孔分子筛结构及晶型的完整性越好。进一步的研究表明，模板剂脱除之后，Ti-TMS2结构的晶体完整性和稳定性明显不如Ti-TMS1的好，且Ti-TMS1的介孔结构优于Ti-TMS2的介孔结构。     

TiO2/Eu-MCM纳米超分子材料的组装和光催化性能

利用有机相-水相界面共沉淀溶胶支持自组装方法制备粒径为15 nm、孔径为8 nm的分子筛Eu-MCM, 它拥有734 m²/g的比表面积和1.49 cm³/g的比孔容. 把TiO₂组装到Eu-MCM的孔道中, 组装成TiO₂/Eu-MCM纳米复合材料. XRD, RAMAN和选区电子衍射花样分析表明纳米复合材料中的TiO₂为锐钛型. TiO₂/Eu-MCM的发光表现为Eu^3＋离子的特征光谱, 激发峰分别为342 (⁵L₁₀), 358 (⁵L₉), 378 (⁵L₇), 390 (⁵L₆), 411 (⁵D₃), 462 (⁵D₂)和524 (⁵D₁) nm; 发射峰为579, 592, 613, 653和701 nm, 归属于⁵D₀→⁷F_J (J＝0, 1, 2, 3, 4)组态间的跃迁. 纳米复合材料的发光强度都要比Eu-MCM的发光强, 其中43%TiO₂/Eu-MCM的发光最强. 荧光和紫外漫反射结果表明客体TiO₂对主体分子筛存在能量传递效应. 在微弱的紫外灯光照射下, TiO₂/Eu-MCM纳米复合材料对苯酚的光催化氧化性能和其发光强度具有一定的相关性. 29%TiO₂/Eu-MCM的纳米复合材料拥有的比表面积、孔容和孔径分别为204 m²/g, 0.24 cm³/g和4.7 nm. 29%TiO₂/Eu- MCM对苯酚具有68%的最高光催化氧化产率和85%催化氧化选择性.     

微波法研制碱土金属氧化物负载型MCM-48碱性介孔材料

以立方相介孔分子筛MCM-48为载体,用微波辐射分散MgO或CaO和醋酸镁溶液浸渍等方法研制碱性介孔材料。MCM-48能经受微波辐射,负载碱性客体之后也保持介相结构。异丙醇分解探针反应表明:载体本身没有碱催化活性,而碱性MCM-48介孔材料的活性随温度升高而提高。本文还对介孔材料在微波分散和碱性催化方面的特点进行分析。