双杂原子介孔材料的合成及催化应用

在强酸性条件下,采用沸石前驱体溶液与表面活性剂自组装的方法,合成双杂原子掺杂的介孔催化材料Sn/Ti-MS-1. 表征结果显示,Sn/Ti-MS-1具有典型的介孔结构,骨架中含有TS-1沸石的结构单元. 在苯酚和2,3,6-三甲基苯酚的双氧水氧化反应中,焙烧前后的Sn/Ti-MS-1均表现出了良好的催化反应活性,表明其钛物种具有良好的热稳定性,并且在大分子氧化反应应用中具有明显的优势. 同时,这种Sn/Ti双杂原子介孔材料显示了较快的催化反应速率.     

分级孔沸石材料的合成、表征及其催化应用*

本文主要阐述了分级孔沸石材料的合成、表征及其催化应用的最新进展。基于分级孔的产生机制,系统地评述了分级孔沸石材料合成方法,包括水热处理、化学处理、酸浸法、碱浸法以及模板剂法,重点对模板剂合成法进行了分类阐述,进而对分级孔沸石材料的结构鉴定、织构性能、水热稳定性及酸性测定相关的表征方法进行了综述;最后结合实例说明了分级孔沸石材料在催化反应中的应用前景。     

氩吸附法研究多级孔分子筛的孔结构

采用不同方法分别制备了双介孔分子筛、介微孔分子筛及介孔沸石材料,利用氩吸附法并结合XRD技术表征了多级孔分子筛的孔结构。探讨了适用于多级孔分子筛的孔径分布计算方法,揭示了不同类型吸附等温线与孔径分布、孔型及孔容等之间的关系。研究表明,对于多级孔分子筛、微孔和介孔的孔径分布分别用SF法和BJH法计算较适宜,全孔分析可用NLDFT法计算。通过对TS-1介孔沸石的孔结构分析发现, TPAOH 在改性制备介孔TS-1的过程中起到了生成介孔及促进二次晶化的双重作用。     

新型HPW/SiO2复合介孔材料的合成与表征

合成了一种新型的HPW/SiO2复合介孔材料,通过XRD,TEM,UV-Vis和FTIR等表征证明,HPW均匀且稳定地包藏到介孔材料由SiO2网络组成的孔壁之中.催化结果表明,其在大分子催化反应中有较高的活性,在酯化反应中连续循环使用未发现活性组分流失,表明其在多相催化和大分子催化反应中有较好的工业应用前景.     

由沸石纳米粒子自组装制备具有高催化活性中心和水热稳定的新型介孔分子筛材料

 人们合成了一系列介孔分子筛材料，并发现它们在催化、吸附与分离以及化学组装制备先进材料和分子器件等方面具有很大的潜在应用价值．但是，介孔分子筛材料相对于微孔沸石分子筛存在着两个致命弱点：较低的水热稳定性和较不活泼的催化活性中心．这两个弱点大大地影响了介孔分子筛在催化反应中的广泛应用．本文系统地综述了最近几年利用沸石纳米粒子自组装制备具有高催化活性中心和水热稳定的介孔分子筛材料的研究进展．这包括利用硅铝沸石纳米粒子自组装制备具有强酸性和水热稳定的新型介孔硅铝分子筛材料，利用钛硅沸石纳米粒子自组装制备具有高催化氧化活性中心和水热稳定的新型钛硅介孔分子筛材料，以及利用含有不同杂原子的沸石纳米粒子自组装制备一系列水热稳定的新型介孔分子筛催化材料．     

新型复合介孔材料HPMo/SBA-15的合成与表征

合成了一种新型复合介孔材料HPMo/SBA-15, 通过XRD, TEM, UV-Vis和IR等方法表征证明HPMo均匀且稳定地包藏到介孔材料SBA-15的由SiO2网络组成的孔壁中. 催化实验结果表明, 该材料在大分子催化裂化反应中具有很高的活性, 在大分子催化氧化反应中连续循环使用未发现活性组分流失, 显示了其在大分子催化和均相催化反应多相化中具有很好的应用前景.     

微乳液法合成沸石/介孔二氧化硅复合微球

利用简单微乳液自组装体系, 制备了介孔二氧化硅与Y型或Ti-MWW沸石晶体复合形成的沸石/介孔二氧化硅微球(ZMMS). 硅源正硅酸四丁酯与阳离子型季铵盐表面活性剂形成稳定的O/W微乳液形成大颗粒, 沸石颗粒由于疏水作用而进入油相, 同时, 季铵盐表面活性剂和正硅酸四丁酯组装形成介孔材料. 优化合成条件可以有效控制复合微球的沸石/介孔二氧化硅质量比(0～2.3)和直径(186～965 μm). 两种沸石/介孔二氧化硅复合微球材料的介孔孔径分别为3.98 nm(Y型沸石)和3.75 nm (Ti-MWW型沸石). Ti-MWW沸石/介孔二氧化硅复合微球在液相催化环氧化反应中表现出良好的机械强度, 并且能够达到与Ti-MWW沸石原粉相当的催化活性.     

介孔沸石分子筛的制备

介孔沸石分子筛是一种含有丰富介孔的结晶沸石,它不同于介孔分子筛和微孔沸石的简单机械混合。它不仅具备微孔沸石高的热和水热稳定性、优异的选择性和活性,而且由于介孔的引入改善了其对大分子的吸附和扩散性能,逐渐成为多孔催化材料研究领域的热点。本文主要从模板法、后处理法和前驱体组装法等方法出发,介绍了介孔沸石分子筛最新的制备方法研究进展。通过对比不同制备方法的优缺点,指出各种方法的改进方向,以期寻求一种较优的合成策略,以满足现今催化领域日益苛刻的要求。     

丝光沸石前驱体组装MCM-41介孔分子筛

MCM-41分子筛是具有单一孔径的长程有序介孔材料,由于孔壁是无定形结构,与微孔沸石晶体相比,水热稳定性较差,这使其在石油炼制和精细化工中的应用受到很大的限制.根据实验发现,如果将一些沸石的前驱结构单元体--即在形成完整的沸石结构前所形成的初级或次级结构单元引入介孔材料,使其转化为介孔孔壁,将会增加介孔材料的短程有序化程度,提高水热稳定性.     

介孔ZSM-5沸石微球催化剂上萘的苄基化反应

以有机硅烷化的二氧化硅为硅源,制备了由纳米粒子聚集而成的、具有晶间和晶内介孔的微球状ZSM-5(MMZ-5)沸石.通过吡啶(Py)和2,6-二叔丁基吡啶(DTBPy)在介孔沸石表面吸附的原位红外测试,对其酸性进行了表征.与微孔ZSM-5沸石相比,MMZ-5沸石上的Lewis酸位和总酸位增加,特别是探针大分子DTBPy(动力学直径约为1.05 nm)可及的Br?nsted酸位显著提高.萘在MMZ-5沸石上的苄基化催化结果表明,反应发生在拥有大量活性位的沸石外表面,大的沸石外表面为该催化反应提供了作用空间,从而提高了沸石活性位的有效利用率,使MMZ-5沸石上萘的苄基化反应活性显著提高,能够生成大分子产物一苄基萘和二苄基萘;其中,一苄基萘的选择性约为79%,且随着反应时间的延长,MMZ-5沸石大的晶内介孔(3-5 nm)为反应提供了有效反应空间,促进一苄基萘向二苄基萘转化.异构体α-一苄基萘和β-一苄基萘的摩尔比值约为83:17,该值不随着温度和转化率的变化而改变.     

介孔分子筛的酸性和水热稳定性

介孔分子筛材料在催化、吸附与分离以及化学组装制备先进材料和分子器件等方面具有潜在的应用价值.但是,由于介孔分子筛材料较低的水热稳定性和较弱的酸性,极大地影响了其在催化研究中的广泛应用.本文系统地综述了最近几年在提高介孔分子筛酸性和水热稳定性的研究工作.其中包括:(1)将超酸组份负载于介孔分子筛的孔道中以达到提高介孔分子筛材料的酸强度的目的;(2)通过在合成介孔分子筛的过程中加入无机盐和有机胺等助剂或采用合适的后处理方法以提高介孔分子筛的水热稳定性;(3)通过新型模板剂来合成具有较高水热稳定性的介孔分子筛材料;(4)利用具有沸石分子筛基本结构单元的沸石分子筛导向剂与表面活性剂自组装来合成具有强酸中心和高温水热稳定的介孔分子筛材料.     

Dual‐Mesoporous ZSM‐5 Zeolite with Highly b‐Axis‐Oriented Large Mesopore Channels for the Production of Benzoin Ethyl Ether

Dual‐mesoporous ZSM‐5 zeolite with highly b axis oriented large mesopores was synthesized by using nonionic copolymer F127 and cationic surfactant CTAB as co‐templates. The product contains two types of mesopores—smaller wormlike ones of 3.3 nm in size and highly oriented larger ones of 30–50 nm in diameter along the b axis—and both of them interpenetrate throughout the zeolite crystals and interconnect with zeolite microporosity. The dual‐mesoporous zeolite exhibits excellent catalytic performance in the condensation of benzaldehyde with ethanol and greater than 99 % selectivity for benzoin ethyl ether at room temperature, which can be ascribed to the zeolite lattice structure offering catalytically active sites and the hierarchical and oriented mesoporous structure providing fast access of reactants to these sites in the catalytic reaction. The excellent recyclability and high catalytic stability of the catalyst suggest prospective applications of such unique mesoporous zeolites in the chemical industry.     

Catalytic benzene alkylation over mesoporous zeolite single crystals: improving activity and selectivity with a new family of porous materials

Mesoporous zeolite single-crystal catalysts are shown to be both more active and more selective than conventional zeolite catalysts in the alkylation of benzene with ethene. The superior catalytic properties are ascribed to improved mass transport in the mesoporous zeolite crystals. Thus, mesoporous zeolite single-crystal catalysts combine the high acidity, shape-selectivity, and hydrothermal stability of zeolites with the efficient mass transport that is typically achieved in mesoporous materials.     

ZSM-5 zeolite single crystals with b-axis-aligned mesoporous channels as an efficient catalyst for conversion of bulky organic molecules

The relatively small and sole micropores in zeolite catalysts strongly influence the mass transfer and catalytic conversion of bulky molecules. We report here aluminosilicate zeolite ZSM-5 single crystals with b-axis-aligned mesopores, synthesized using a designed cationicamphiphilic copolymer as a mesoscale template. This sample exhibits excellent hydrothermal stability. The orientation of the mesopores was confirmed by scanning and transmission electron microscopy. More importantly, the b-axis-aligned mesoporous ZSM-5 shows much higher catalytic activities for bulky substrate conversion than conventional ZSM-5 and ZSM-5 with randomly oriented mesopores. The combination of good hydrothermal stability with high activities is important for design of novel zeolite catalysts. The b-axis-aligned mesoporous ZSM-5 reported here shows great potential for industrial applications.     

Availability and interconnectivity of pores in mesostructured ZSM-5 zeolites by the adsorption and diffusion of mesitylene

Probing the mesopore architecture in mesoporous zeolites is of importance for large scale applications of the materials. In this work, the adsorption and diffusion of mesitylene with larger molecule size in mesoporous ZSM-5 zeolites were carried out, in order to acquaint the availability and interconnectivity of mesopores in zeolite crystals. The comparisons of the shape of adsorption isotherms and the mesopore volume calculated from mesitylene and N₂ adsorption in mesoporous ZSM-5 zeolites with different mesoporosities can be used to discriminate two cases of mesopores: accessible mesopores connected to external surface of the zeolite crystals and non-accessible meso-voids that are occluded in the microporous matrix. Furthermore, the effective diffusivity and activation energy of mesitylene in mesoporous ZSM-5 extracted from ZLC desorption curves as a function of mesopore volume calculated from mesitylene adsorption reveal the enhancement of mesopore interconnectivity to molecule diffusion in zeolite crystals.     

介孔丝光沸石的制备及其对重芳烃转化反应的催化性能

 用不同浓度的 NaOH 溶液对丝光沸石进行处理制备了具有复合孔道结构的介孔丝光沸石, 并采用 X 射线衍射、扫描电子显微镜、透射电子显微镜和 N2 吸附-脱附等方法对其进行了表征. 结果表明, 随着 NaOH 溶液浓度的升高, 介孔丝光沸石的粒径逐渐变小, 分子筛表面的介孔逐渐丰富, 孔径分布逐渐变宽, 介孔体积逐渐增大呈线性关系. 当 NaOH 浓度为 0.50 mol/L 时, 介孔丝光沸石的形貌变为空心沸石微囊或微囊壁. 介孔的增加产生扩散效应, 适当的 NaOH 溶液处理有利于提高丝光沸石对 C9 和 C10 芳烃的转化能力.     

Hydrothermally Stable and Catalytically Active Ordered Mesoporous Materials Assembled from Preformed Zeolite Nanoclusters

Microporous zeolites are widely used commercial catalysts, but their applications are intrinsically limited by their small channel diameters. Recent progress in solving this is used to ordered mesoporous materials such as MCM-41, HMS and SBA-15. These mesoporous materials have pore diameters of 30–60 Å and exhibit catalytic properties for the catalytic conversion of bulky reactants, but unfortunately, when compared with microporous zeolites, the catalytic activity and hydrothermal stability are relatively low, which severely hinders their practical applications. The relatively low catalytic activity and hydrothermal stability can be attributed to the amorphous nature of the mesoporous walls. We review here that the assembly of preformed zeolite precursors with surfactants can synthesize a series of ordered mesoporous materials, which include (1) strongly acidic and hydrothermally stable mesoporous aluminosilicates synthesized in alkaline media; (2) strongly acidic and hydrothermally stable mesoporous aluminosilicates synthesized in strongly acidic media; (3) hydrothermally stable mesoporous titanosilicates with catalytically active titanium species in oxidations; (4) hydrothermally stable mesoporous ferrisilicates. This work would open a door for the industrial application of mesoporous materials as catalysts for large molecules.     

Polyelectrolyte-surfactant complex as a template for the synthesis of zeolites with intracrystalline mesopores

Mesoporous zeolite silicalite-1 and Al-ZSM-5 with intracrystalline mesopores were synthesized with polyelectrolyte-surfactant complex as the template. Complex colloids were first formed by self-assembly of the anionic polymer poly(acrylic acid) (PAA) and the cationic surfactant cetyltrimethylammonium bromide (CTAB) in basic solution. During the synthesis procedure, upon the addition of the silica source, microporous template (tetrapropylammonium hydroxide), and NaCl, these PAA/CTA complex colloids underwent dissociation and gave rise to the formation of hollow silica spheres with mesoporous shells templated by CTAB micelles and PAA domains as the core. Under hydrothermal treatment, the hollow silica spheres gradually merged together to form larger particles with the PAA domains embedded as the space occupant, which acted as a template for intracrystalline mesopores during the crystallization of the zeolite framework. Amphiphilic organosilane was used to enhance the connection between the PAA domain and the silica phase during the synthesis. After calcination, single crystal-like zeolite particles with intracrystalline mesopores of about 5-20 nm were obtained, as characterized by X-ray diffraction, scanning electron microscopy, transmission electron microscopy, and N(2) adsorption measurements. With the addition of an aluminum source in the synthesis, mesoporous zeolite Al-ZSM-5 with intracrystalline mesopores was also synthesized, and enhanced catalytic property was observed with mesoporous Al-ZSM-5 in acetalization of cyclohexanone with methanol.     

Study on the Pyrolysis of Cellulose for Bio-Oil with Mesoporous Molecular Sieve Catalysts

Mesoporous materials possess a hexagonal array of uniform mesopores, high surface areas, and moderate acidity. They are one of the important catalysts in the field of catalytic pyrolysis. In this paper, mesoporous materials of Al-MCM-41, La-Al-MCM-41, and Ce-Al-MCM-41 were synthesized, characterized, and tested as catalysts in the cellulose catalytic pyrolysis process using a fixed bed pyrolysis reactor. The results showed that mesoporous materials exhibited a strong influence on the pyrolytic behavior of cellulose. The presence of these mesoporous molecular sieve catalysts could vary the yield of products, which was that they could decrease the yield of liquid and char and increase the yield of gas product, and could promote high-carbon chain compounds to break into low-carbon chain compounds. Mesoporous molecular sieve catalysts were benefit to the reaction of dehydrogenation and deoxidation and the breakdown of carbon chain. Further, La-Al-MCM-41 and Ce-Al-MCM-41 catalysts can produce more toluene and 2-methoxy-phenol, as compared to the non-catalytic runs.