介孔分子筛制备技术新进展—二次合成、超分子自组装和介孔生成剂法

具有内部介孔结构的多级孔分子筛兼具微孔分子筛和介孔材料的功能, 拥有良好的传质和催化特性. 在过去的几十年内, 介孔分子筛在催化、 吸附和分离领域发展迅速. 近年来, 新型合成方法的开发在很大程度上实现了介孔分子筛孔道结构、 组分及形貌灵活可控的调节. 本综述讨论了近期出现的多种新合成路径, 重点介绍了近期发展起来的二次合成制备低硅/铝介孔分子筛、 超分子自组装合成介孔分子筛及有机小分子原位合成介孔分子筛技术. 对这些合成技术的机理进行了讨论, 以期为介孔分子筛未来的发展提供思路. 文章的最后还讨论了不同的合成策略所面临的一些关键性挑战.     

介孔分子筛制备技术新进展——二次合成、超分子自组装和介孔生成剂法（英文）

具有内部介孔结构的多级孔分子筛兼具微孔分子筛和介孔材料的功能,拥有良好的传质和催化特性.在过去的几十年内,介孔分子筛在催化、吸附和分离领域发展迅速.近年来,新型合成方法的开发在很大程度上实现了介孔分子筛孔道结构、组分及形貌灵活可控的调节.本综述讨论了近期出现的多种新合成路径,重点介绍了近期发展起来的二次合成制备低硅/铝介孔分子筛、超分子自组装合成介孔分子筛及有机小分子原位合成介孔分子筛技术.对这些合成技术的机理进行了讨论,以期为介孔分子筛未来的发展提供思路.文章的最后还讨论了不同的合成策略所面临的一些关键性挑战.     

pH对两步法非离子模板合成MSU-X类硅基介孔结构的影响

采用两步法以非离子型表面活性剂Tween 20为模板剂合成硅基介孔材料, 研究了pH对介孔材料结构的影响. 结果表明, 没有氟离子存在且模板剂浓度较低(约为2%(w))的条件下, 在弱酸性环境中(pH=3.32-4.26)可以制备有序的MSU-X类硅基介孔材料, 本研究中的简单合成体系有助于查明MSU-X合成机理. 对所得介孔材料测试表明, 在同样的合成体系中, 随着体系pH的变化, 所得硅基介孔材料的形貌和孔壁结构都发生了变化.     

树枝状介孔二氧化硅的研究进展

介绍了树枝状介孔二氧化硅的三种合成方法,分别是微乳液合成、两相界面合成及球形胶束自组装合成法,为精确调节树枝状介孔二氧化硅的结构,探讨了不同方法可能的形成机理。由于球形胶束自组装合成法的绿色经济,重点讨论了球形胶束自组装合成法的发展及形成机理。介绍了树枝状介孔二氧化硅纳米材料在催化和生物医学方面的应用效果,并对树枝状介孔二氧化硅的合成方法和在催化、生物医学和能源领域的应用前景进行了展望。     

含钴介孔分子筛催化热解乙醇制备纳米碳管

以CTAB为模板剂,硅酸钠、氯化钴为原料,通过水热法合成含钴介孔分子筛(Co-MCM-41)。以所合成的Co-MCM-41做催化剂,采用化学气相沉积(CVD)法催化热解乙醇制备纳米碳管。通过XRD、FT-IR、TEM、N2吸附-脱附和Raman光谱等分析手段对所合成的介孔分子筛和纳米碳管进行了表征。结果表明:合成的Co-MCM-41样品具有MCM-41的介孔结构,比表面积较大且介孔有序性较好。以所合成的含钴介孔分子筛催化热解乙醇制备出管径均匀、管壁较厚、顶端开口的多壁纳米碳管。     

多阶有序多孔炭的软模板法合成与结构控制

多阶有序多孔炭材料综合了多种多孔炭材料的结构优点,在催化、吸附、储能、电化学等方面具有潜在的重要应用。多阶有序多孔炭材料的合成方法很多,到目前为止,模板法是控制孔结构和调节尺寸的最有效方法。在模板法中,软模板法因为其工艺简单、省时、成本低、环境污染小等优势,近些年来广泛被人们采用。用软模板法合成的多阶有序多孔炭包括:大孔-介孔炭,介孔-微孔炭,介孔-介孔炭,大孔-介孔-微孔炭等。本文对多阶有序多孔炭的软模板法合成与结构控制进行了综述。总结了软模板法在实现上述材料孔结构控制中的影响因素。     

介孔二氧化钛的合成及其对甲基橙降解的光催化活性

以十六烷基三甲基溴化铵为模板剂,通过水解钛酸正丁酯合成了介孔二氧化钛分子筛,探讨了合成条件的影响。采用X射线粉末衍射(XRD)、红外光谱(FT-IR)、透射电子显微镜(TEM)和N2吸附-脱附等技术对介孔二氧化钛的晶相、结构、形貌、比表面积和孔径分布进行了表征。实验结果表明:得到的介孔二氧化钛分子筛的孔径为4-4.3nm,用抽提的方法去除模板剂得到的介孔二氧化钛的比表面积比焙烧的要高。以甲基橙为模型污染物,检验了所合成介孔二氧化钛的光催化性质。     

聚合物基模板制备中空介孔材料

中空介孔材料,尤其是硅基和碳基中空介孔材料,由于其孔道结构丰富、孔径可调、高比表面积、可容纳客体分子、良好的热稳定性和化学稳定性等特点已被广泛应用于催化、能量储存等众多领域。模板法是目前为止制备中空介孔结构最有效的方法之一,其最大特点是可以通过对模板的调控来实现对中空介孔结构的控制。聚合物基模板种类繁多,主要包括嵌段共聚物、聚合物乳胶粒、天然/合成生物大分子及复杂结构高分子等;与传统的表面活性剂/无机氧化物模板相比,其自组装形态更加丰富,结构更易进行功能化修饰。同时,以聚合物为模板的合成反应条件更加温和可控,更有利于合成形态各异、功能丰富的中空介孔材料。本文综述了近年来不同聚合物基模板合成中空介孔材料的研究进展,并着重介绍了贵金属粒子负载的中空介孔材料在催化载体领域的应用;同时,指出了当前阻碍中空介孔材料发展的问题,并对其在催化领域的应用前景进行了展望。     

介孔金属氧化物催化剂的合成与快速开发

介孔金属氧化物以其独特的高度有序介孔结构和化学物理特性,在化学、燃料和石油化工等领域有极大的应用前景,越来越受到人们的关注。本文介绍一系列简单通用的介孔金属氧化物纳米组装合成方法,以及基于此类方法,通过调节介孔材料的氧化还原性、酸碱性和半导体性质,可实现对催化剂催化性能的优化。同时,还重点介绍高精印刷技术与纳米组装合成相结合的复合介孔金属氧化物合成方法,并展望了介孔金属氧化物催化剂的未来发展趋势。     

介孔分子筛V-MCM-41的水热法制备与合成机理

 以十六烷基三甲基溴化铵为模板剂,廉价的工业级高模数比(3.3)的硅酸钠为硅源,通过水热法合成了V-MCM-41介孔分子筛. 考察了合成条件对产物织构的影响,并采用低温氮吸附法分析探讨了介孔分子筛V-MCM-41的合成机理. 结果表明,模板剂用量、 pH值、加料方式、晶化温度、晶化时间、陈化时间和焙烧气氛等合成条件对介孔分子筛的制备均有影响,其中晶化温度、 pH值和模板剂用量的影响最为明显. X射线衍射谱表明合成的介孔分子筛具有六方晶体结构. 红外光谱和紫外可见光谱表明V进入了介孔分子筛的骨架结构.     

高温水热合成具有超低介电常数的规则介孔氧化硅材料

分别以高分子三嵌段共聚物P123(PEO₂₀-PPO₇₀-PEO₂₀)和F127(PEO₁₀₆-PPO₇₀-PEO₁₀₆)为模板剂, 通过高温水热法制备了具有超低介电常数的规则介孔氧化硅材料(OMSs). 当合成温度达到200℃时, 得到的产物仍可保持规则的介孔结构. X射线衍射和氮气吸附结果表明, OMSs系列材料具有规则的二维六方或体心立方介孔结构、 大的比表面积和孔容及均一的孔径分布. ²⁹Si MAS NMR分析表明, OMSs与低温(100℃)合成产物相比具有更高的骨架缩合度, 从而具有优异的水热稳定性. 由于具有大的孔容和高的骨架缩合度, OMSs表现出了超低的介电常数. 以P123为模板剂, 200℃下合成的OMS的介电常数可达1.31. OMSs作为一类稳定的超低介电常数材料, 对于绝缘材料的发展具有潜在的应用价值.     

Synthesis and Characterization of Microporous Silica Prepared with Sodium Silicate and Organosilane Compounds

Microporous silica gels were prepared in the pH range of 3–4 using sodium silicate as a silica source. Surface polarity of these gels was modified by grafting hydrophobic groups into the silica gel matrix with the help of hydrophilic solvents (acetone, acetonitrile, ethanol and methanol) and alkoxysilane compounds containing nonhydrolyzable alkyl groups. The porous framework and hydrophobicity of the silica gels were evaluated using nitrogen adsorption/desorption and water adsorption measurement techniques. All the measured isotherms were found to be type I which is indicative of microporosity. The surface area and microporosity of these samples were estimated by analyzing the measured nitrogen adsorption/desorption data using BET, Langmuir and Dubinin-Radushkevich (D-R) adsorption isotherms. The micropore size distribution was determined from their nitrogen adsorption isotherms using the slit-pore model of the Horvath-Kawazoe equation. Silica gels with high surface area (over 500 m²/g) as well as high microporosity (over 0.2 cc/g) were obtained at gelation pH of 3.50 from the water-solvent system.     

Comparison of solvent extraction and solid-phase extraction for the determination of organochlorine pesticide residues in water.

Solid-phase extraction (SPE) of organochlorine pesticide residues from environmental water samples was evaluated using octadecyl (C18)-bonded porous silica. The efficiency of SPE of these pesticide residues from reagent water samples at 1-5 micrograms dm-3 levels was compared with those obtained by solvent extraction with hexane and Freon TF (trichlorotrifluoroethane). Average recoveries exceeding 80% for these organochlorine pesticides were obtained via the SPE method using small cartridges containing 100 mg of 40 microns C18-bonded porous silica. The average recovery by solvent extraction with hexane and Freon TF exceeded 90% in both instances. It was concluded that the recoveries and precision for the SPE of organochlorine pesticides were poorer than those for the solvent extraction method. Organochlorine pesticide residue levels in environmental water samples from two major rivers flowing through predominantly rice-growing areas were monitored by gas chromatography using the solvent extraction method with hexane. Exceptionally high levels of organochlorine pesticide residues such as BHC, DDT, heptachlor, endosulfan and dieldrin were found in these water samples.     

酸性条件下纯硅六方介孔分子筛的合成(Ⅱ)合成温度、时间的影响及其与碱性合成的比较

本文以十六烷基三甲基溴化铵为模板剂,正硅酸乙酯为硅源,考察了反应温度和时间对酸性条件下合成纯硅六方介孔分子筛的影响,并与碱性合成路径相比较。结果表明,由于无机物种与表面活性剂之间的相互作用不同,六方介孔分子筛的酸性合成经历了与碱性合成完全不同的机理。对要到性合成来说,由于六方结构的形成取决于稳定的模板胶束的存在,并不特别依赖于硅物种的缩合,故高温、长反应时间等有利于缩合的因素对提高产品质量几乎没有促进作用,较高的反应温度甚至起反作用。因此,酸性合成宜采用室温条件。     

Synthesis of Monodisperse Hollow Carbon Nanocapsules by Using Protective Silica Shells

Monodisperse hollow carbon nanocapsules (<200 nm) with mesoporous shells were synthesized by coating their outer shells with silica to prevent aggregation during their high‐temperature annealing. Monodispersed silica nanoparticles were used as starting materials and octadecyltrimethoxysilane (C18TMS) was used as a carbon source to create core–shell nanostructures. These core–shell nanoparticles were coated with silica on their outer shell to form a second shell layer. This outer silica shell prevented aggregation during calcination. The samples were characterized by TEM, SEM, dynamic light scattering (DLS), UV/Vis spectroscopy, and by using the Brunauer–Emmett–Teller (BET) method. The as‐synthesized hollow carbon nanoparticles exhibited a high surface area (1123 m² g^?1) and formed stable dispersions in water after the pegylation process. The drug‐loading and drug‐release properties of these hollow carbon nanocapsules were also investigated.     

硅源对MCM-22分子筛合成及物化性质的影响

在动态水热条件下,研究了硅溶胶、白炭黑、硅酸及硅胶为硅源时对MCM-22分子筛合成及物化性质的影响。以硅溶胶、白炭黑、硅酸三种硅源均可合成出高结晶度且无杂晶的片状MCM-22分子筛,其平均粒径分别为190、220和750 nm。硅源影响分子筛的聚集形态,三种硅源分别形成晶粒分散、晶粒半分散及晶粒聚集形态。三组样品的酸强度分布基本一致,都具有较多的中强酸分布,由硅溶胶和硅酸所得MCM-22分子筛在中强酸范围具有更高的B/L酸比值,以白炭黑合成的分子筛总酸量最高。NMR结果表明,样品中的铝以骨架铝为主,不存在明显的非骨架铝。由于硅胶对合成体系中游离水的吸附作用,水热反应难以发生,不能得到MCM-22分子筛,硅胶作为分子筛合成硅源时需要选择合适的反应条件。     

Effect of embedded metal compound on porosity of silica colloids prepared by spray reaction of silicon tetrachloride

Attempts to prepare macroporous silica particles and metal-compound-nanoparticle-embedded silica microspheres were carried out using reactions between silicon tetrachloride and ultrasonic generating microdroplets including metal (Na, K, Al, Ni, Ti, Pt) compounds. Samples were collected by dry and wet processes. In the case of using nickel and aluminum compounds, acid-treated samples were also prepared. The obtained samples were characterized by scanning electron microscopy, X-ray fluorescence spectroscopy, powder X-ray diffractometry, mercury porosimetry, and the nitrogen adsorption method. The macroporous silica particles were prepared by removing the salt crystals, such as NaCl and KCl, formed in the silica frame. For acid-resistant metals, platinum- and titanium-compound nanoparticles are easily embedded in silica microspheres using these metal-compound solutions. For acid-soluble metals, aluminum- and nickel-compound-nanoparticle-embedded silicas were prepared by applying neutralization of the collection water. Micropores and mesopores were produced in wet-process samples. Acid treatment induced the increase of micropore volumes.     

Non-supercritically dried silica–silica composite aerogel and its possible application for confining simulated nuclear wastes

The simpler non-supercritical drying approach has been used for the first time for the preparation of silica–silica composite aerogels (CA) and the efficiency of the process being demonstrated by testing the use of the aerogels for simulated high level nuclear waste confinement. Compositions of 5, 10, 20, 30, 40 and 50 wt% of silica (aerosil® 380) in silica–aerogel were prepared by introducing pyrogenic silica in to silica sol derived by hydrolysis of Tetraethoxy silane (TEOS). The silica–silica composite aerogels (CA) possessed very high surface area and low bulk densities. The effectiveness of the prepared composite aerogels as precursor for high level nuclear waste immobilized glass is also presented. Neodymium nitrate dissolved in isopropanol is used to simulate +3 valent actinides. The stability of neodymium in the glass matrix has been found to be extremely high. Transmission electron microscopy (TEM) has been used to characterise the aerogels as well as neodymium incorporated sintered gels. X-ray diffraction (XRD) studies of the sintered samples reveal the formation of neodymium silicates.     

Plasma polymerization of acetylene onto silica: an approach to control the distribution of silica in single elastomers and immiscible blends

Surface modification of silica by acetylene plasma polymerization is applied in order to improve the dispersion in and compatibility with single rubbers and their blends. Silica, used as a reinforcing filler for elastomers, is coated with a polyacetylene (PA) film under vacuum conditions. Water penetration measurements show a change in surface energy due to the PA‐film deposition. The weight loss measured by thermo‐gravimetric analysis (TGA) is higher for the PA‐coated silica compared to the untreated filler, confirming the deposition of the PA film on the silica surface. Time of flight‐secondary ion mass spectrometry (ToF‐SIMS) shows the well‐defined PA cluster peaks in the high mass region. Scanning electron microscopy (SEM) measurements show silica aggregates, coalesced by the coating with smooth and uniform surfaces, but without significant change in specific surface area. Elemental analysis by energy dispersive X‐ray spectroscopy (EDX) measurements also confirms the deposition of the polymeric film on the silica surface, as the carbon content is increased. The performance of single polymers and their incompatible blends based on S‐SBR and EPDM, filled with untreated, PA‐ and silane‐treated silica, is investigated by measurements of the bound rubber content, weight loss related to bound rubber, cure kinetics, reinforcement parameter, Payne effect, and mechanical properties. The PA‐ and silane‐modified silica‐filled pure S‐SBR and EPDM samples show a lower filler–filler networking compared to the unmodified silica‐filled elastomers. Decrease in the reinforcement parameter (α_F) for the plasma‐polymerized silica‐filled samples also proves a better dispersion compared to silane‐modified and untreated silica‐filled samples. On the other hand, the PA‐silica‐filled samples show a higher bound rubber content due to stronger filler–polymer interactions. Finally, the PA‐silica‐filled pure EPDM and S‐SBR/EPDM blends show high tensile strength and elongation at break values, considered to be the result of best dispersion and compatibilization with EPDM. Copyright © 2008 John Wiley & Sons, Ltd.     

A Urea Precursor to Synthesize Carbon Nitride with Mesoporosity for Enhanced Activity in the Photocatalytic Removal of Phenol

A urea precursor was used for the first time to prepare mesoporous carbon nitride (MCN) by a thermal polymerization process with silica nanospheres as a hard template. Although the prepared MCN samples have similar structures and optical properties, it was revealed that the specific surface area, pore‐size distribution, and morphology of the MCN samples depend on the initial mass ratio of urea to silica. Compared to the bulk carbon nitride (BCN) that only gave 20 % phenol removal (6 h of irradiation), the activities can be enhanced up to 74 % on MCN samples for photocatalytic removal of phenol under visible‐light irradiation. The highest conversion was obtained on MCN with an initial mass ratio of urea to silica of 5, which has high surface area of 191 m² g^?1 and a nanoporous structure with uniform pore‐size distribution of 7 nm. In addition to the high activity, the MCN sample also showed high photocatalytic stability.