八羟基喹啉铁（Ⅱ）／MCM—41对苯酚羟化的催化作用

利用ＭＣＭ－４１中孔分子筛为载体，制备了我载型八羟基喹啉铁／ＭＣＭ－４１催化剂。ＸＲＤ，ＩＲ证明八羟基喹吉林 铁配合物成功地负载于ＭＣＭ－４１分子筛中。考察了八羟基喹啉铁／ＭＣＭ－４１对苯酚羟化反应的催化作用，和未负载的配合物相比，苯酚的转化率，对苯二酚的选择以及Ｈ２Ｏ２的利用率都有显著的提高。     

六方介孔硅酸盐的制备,表征及对苯酚羟化反应的催化作用

在室温下制备了Ｃｕ－ＨＭＳ（六方介孔硅酸盐）介孔含Ｃｕ杂原子分子筛，利用ＸＲＤ、ＩＲ和ＥＳＲ对其进行了表征，表明Ｃｕ原子已进入硅酸盐骨架．探讨了这种新型杂原子分子筛对苯酚羟化反应的催化作用，发现Ｃｕ－ＨＭＳ与Ｖ－ＨＭＳ，Ｔｉ－ＨＭＳ，ＴＳ－１，Ｃｕ－ＺＳＭ－５和Ｃｕ－Ｙ相比，具有较高的催化活性．研究了反应介质及ｐＨ值对苯酚羟化反应的影响，并给出了相应的反应机理     

八羟基喹啉铁(Ⅱ)/MCM-41对苯酚羟化的催化作用

利用ＭＣＭ－４１中孔分子筛为载体，制备了负载型八羟基喹啉铁（Ⅱ）／ＭＣＭ－４１（简记为Ｆｅ（Ⅱ）－Ｑｘ／ＭＣＭ－４１）催化剂．ＸＲＤ，ＩＲ证明八羟基喹啉铁（Ⅱ）配合物成功地负载于ＭＣＭ－４１分子筛中．考察了八羟基喹啉铁（Ⅱ）／ＭＣＭ－４１对苯酚羟化反应的催化作用，和未负载的配合物相比，苯酚的转化率、对苯二酚的选择性以及Ｈ２Ｏ２的利用率都有显著的提高．同时也探讨了温度、反应介质及介质ｐＨ值对苯酚羟化反应的影响．结果表明，随着温度的提高，苯酚的转化率增加，但温度太高，易导致副产物增多；有机溶剂不利于羟化反应的进行，水是实验条件下苯酚羟化反应的最佳反应介质；在一定程度上，ｐＨ值越低，越有利于反应活性的提高，若ｐＨ值太低，活性反而下降，ｐＨ值升高不利于苯酚羟化反应的进行．该催化剂也具有较高的稳定性．     

CuZSM-5分子筛上苯酚羟化制苯二酚

在Ｎａ２Ｏ－ＳｉＯ２－ＣｕＯ－Ｈ２Ｏ体系中以１５％ＴＰＡＢｒ－８５％ＨＭＤＡ为模板剂合成了ＣｕＺＳＭ－５分子筛，并用ＸＲＤ，ＩＲ及ＳＥＭ等方法进行了表征，考察了ＣｕＺＳＭ－５分子筛催化苯酚与过氧化氢的羟化活性，研究了催化剂用量、反应温度、反应时间及ｎ（ＰｈＯＨ）／ｎ（Ｈ２Ｏ２）等对羟化活性的影响．     

CuZSM—5分子筛上苯酚羟化制苯二酚

在Ｎａ２Ｏ－ＳｉＯ２－ＣｕＯ－Ｈ２Ｏ体系中以１５％ＴＰＡＢｒ－８５％ＨＭＤＡ为模板剂合成了ＣｕＺＳＭ－５分子筛，并用ＸＲＤ，ＩＲ及ＳＥＭ等方法进行了表征，考察了ＣｕＺＳＭ－５分子筛催化苯酚与过氧化氢的羟化活性，研究了催化剂用量，反应温度，反应时间及ｎ（ＰｂＯＨ）／ｎ（Ｈ２Ｏ２）等对羟化活性的影响。     

超大孔Fe和V—Ti分子筛的合成

水热法合成了具有超大孔ＭＣＭ－４１分子筛结构的含Ｆｅ和Ｖ－Ｔｉ分子筛，通过ＸＲＤ，骨架ＩＲ，ＥＳＲ，＾２９ＳｉＭＡＳ ＮＭＲ，紫外漫反射等测试表征证实，Ｆｅ原子在ＦｅＭＣＭ－４１分子筛骨架上，Ｖ和Ｔｉ同是进入Ｖ－ＴｉＭＣＭ－４１分子筛骨架。     

纯硅MCM—41中孔分子筛合成因素的研究：Ⅰ.Na^＋,K^＋阳离子对合成的 …

本文采用表面活性剂十六烷基三甲基溴经铵，在ＯＨ－ＳｉＯ２－Ｃ１６ＴＡＢｒ－Ｈ２Ｏ体系中分别和利用室温，水热及干粉法进行了纯硅ＭＣＭ－４１中孔分子筛的合成，考察了阳离子Ｎａ＾＋，Ｋ＾＋对ＭＣＭ－４１合成及稳定性的影响。     

MCM－41中孔分子筛的合成及其性质

以十六烷基三甲基溴化铵（ＣＴＡＢ）作模板剂，研究了水热体系中中孔ＭＣＭ－４１分子筛的合成条件。在Ｈ_２Ｏ／Ｓｉ介于１２～１００，Ｓｉ／Ａｌ介于１０～∞，ＣＴＡＢ／Ｓｉ介于０．０８～０．２时，可以合成出ＭＣＭ－４１分子筛。在加入煤油等混合烃的合成体系中，可以合成出孔径大于４ｎｍ的ＭＣＭ－４１分子筛。用ＸＲＤ、ＳＥＭ、Ｎ_２吸附对合成样品加以表征，证明它们具有典型的中孔分子筛特性。探针反应证明它具有中强酸中心。     

超大孔Fe和V－Ti分子筛的合成

水热法合成了具有超大孔ＭＣＭ－４１分子筛结构的含Ｐｅ和Ｖ－Ｔｉ分子筛，通过ＸＲＤ、骨架ＩＲ、ＥＳＲ、￣（２９）ＳｉＭＡＳＮＭＲ、紫外漫反射等测试表征证实，Ｆｅ原子在ＦｅＭＣＭ－４１分子筛骨架上，Ｖ和Ｔｉ同时进入Ｖ－ＴｉＭＣＭ－４１分子筛骨架。ＦｅＭＣＭ－４１的骨架红外谱除Ｆｅ分子筛的特征吸收峰６６０ｃｍ￣（－１）外，还显示９６０ｃｍ￣（－１）峰，ＥＳＲ谱出现高对称八面体环境Ｆｅ（Ⅲ）信号（ｇ＝２．０）和扭曲四面体环境Ｆｅ（Ⅲ）信号（ｇ＝４．２），而Ｖ－ＴｉＭＣＭ－４１的骨架红外９６０ｃｍ￣（－１）峰强度分别随分子筛中钛或钒的含量线性增强。约在ｇ＝１．９８处出现的超精细结构ＥＳＲ信号表明Ｖ以分散的不流动的Ｖ￣（４＋）形式存在，化学分析结果表明骨架上Ｔｉ和Ｖ原子相互间不排斥。     

Cu修饰的MCM-41的合成、表征及对芳烃羟化反应催化作用的研究

利用MCM-41形成过程中协同自组装的特点,在合成过程中引入Cu(NH₃)₄²⁺,制备出过渡金属表面修饰的纯硅介孔分子筛Cu-MCM-41,采用XRD,ICP,ESR,N₂吸附等手段确定Cu处于MCM-41的表面,取代了端羟基中氢的位置,与骨架桥氧和硅羟基中的氧配位.利用苯酚羟化反应为探针,考察了Cu-MCM-41的催化活性.结果表明,Cu-MCM-41具有很高的苯酚羟化活性,与TS-1分子筛的催化效果相当,对萘酚的羟化活性也较高.     

Ti接枝MCM-41催化剂的结构设计及化学亲和选择性研究

 用二氯化钛茂作为活性物种的来源，利用Si－MCM－41催化剂表面羟基的反应性，得到了Ti接枝MCM－41催化剂的两种结构模型．结构表征结果表明，Ti接枝MCM－41催化剂不仅长程结构好，孔径分布均一，而且催化剂表面活性中心含量高．两种结构模型催化剂上芳烃羟化反应性能表明，Ti接枝MCM－41催化剂表面的亲水／憎水性可以在较宽的范围内调变，从而可实现控制芳烃羟化的化学亲和选择性．另外，研究结果还表明，Ti接枝MCM－41催化剂具有很好的活性稳定性．     

MCM-41介孔分子筛共价键联钴酞菁的制备，表征及性质

采用两种方法将钴酞菁配合物共价联接到介孔分子筛MCM-41的表面：(1) 在MCM-41表面联接含伯胺的有机侧链；(2) 是在MCM-41表面联接含仲胺的有机侧链。含氯磺酸基的钴酞菁与胺反应形成磺酰胺。对得到的主客体化合物用多种物化手段和催化反应进行了表征。结果表明，钴酞菁以单体形式固定在介孔分子筛MCM-41的孔道壁上，在反应条件下固载后的钴酞菁具有高催化活性，同时表现出良好的稳定性，多次重复使用活性没有明显的改变。     

SiO2载体表面原位合成MCM-41的结构特征

以溶液硅源和表面硅源两种合成路线在SiO₂颗粒表面进行了MCM-41的原位合成,结果发现以两种方式均可得到MCM-41的有序结构。溶液硅源原位合成MCM-41的长程结构较好,两种硅源原位合成的MCM-41均能够在脱除模板剂过程中保持其长程有序结构。表面硅源原位合成MCM-41的孔径分布较窄,最可几孔径为3.81nm。本文还考察了OH/CTABr及SiO₂/OH比对表面硅源原位合成MCM-41长程结构特征的影响。     

NMR provides checklist of generic properties for atomic-scale models of periodic mesoporous silicas

MCM-41 and SBA-15 silicas were studied by (29)Si solid-state NMR and (15)N NMR in the presence of (15)N-pyridine with the aim to formulate generic structural parameters that may be used as a checklist for atomic-scale structural models of this class of ordered mesoporous materials. High-quality MCM-41 silica constitutes quasi-ideal arrays of uniform-size pores with thin pore walls, while SBA-15 silica has thicker pore walls with framework and surface defects. The numbers of silanol (Q(3)) and silicate (Q(4)) groups were found to be in the ratio of about 1:3 for MCM-41 and about 1:4 for our SBA-15 materials. Combined with the earlier finding that the density of surface silanol groups is about three per nm(2) in MCM-41 (Shenderovich, et al. J. Phys. Chem. B 2003, 107, 11924) this allows us to discriminate between different atomic-scale models of these materials. Neither tridymite nor edingtonite meet both of these requirements. On the basis of the hexagonal pore shape model, the experimental Q(3):Q(4) ratio yields a wall thickness of about 0.95 nm for MCM-41 silica, corresponding to the width of ca. four silica tetrahedra. The arrangement of Q(3) groups at the silica surfaces was analyzed using postsynthesis surface functionalization. It was found that the number of covalent bonds to the surface formed by the functional reagents is affected by the surface morphology. It is concluded that for high-quality MCM-41 silicas the distance between neighboring surface silanol groups is greater than 0.5 nm. As a result, di- and tripodical reagents like (CH(3))(2)Si(OH)(2) and CH(3)Si(OH)(3) can form only one covalent bond to the surface. The residual hydroxyl groups of surface-bonded functional reagents either remain free or interact with other reagent molecules. Accordingly, the number of surface silanol groups at a given MCM-41 or SBA-15 silica may not decrease but increase after treatment with CH(3)Si(OH)(3) reagent. On the other hand, nearly all surface silanol groups could be functionalized when HN(Si(CH(3))(3))(2) was used.     

Template transformations in preparation of MCM-41 silica

Template transformation in MCM-41 material during thermal treatment under different conditions was investigated on the basis of thermogravimetry (TG-DTA), X-ray diffraction (XRD) and positron annihilation lifetime spectroscopy (PALS). Micelle templated silica was prepared using C18 trimethylammonium bromide. The pore structure of MCM-41 samples obtained after removal of the surfactant in air, argon flow and vacuum was analyzed on the basis of the adsorption isotherms of nitrogen at 77 K and XRD experiments. The TG-DTA experiments confirm the mechanism of the template removal known from literature. However, the sequence of the processes during thermal treatment of as-synthesized sample and temperature of transformations depended strongly on the presence of oxygen and the heating rate. The main template degradation took place below 573 K and was independent of the kind of atmosphere above the sample. Residual carbonaceous species are removed from pores and the external surface of MCM-41 silica upon heating to 823 K by combustion or evaporation. The latter process as well as translocation of liquid-like products of template degradation from the pore interior to external surface was confirmed by PALS experiment in vacuum.     

Metastability of MCM-41 and Al-MCM-41

The apparent stability of MCM-41 and Al-MCM-41 in water was appraised in a series of solubility experiments. MCM-41 is a siliceous, mesoporous material of hexagonal symmetry and exceptionally high surface area first synthesized in 1992. The dissolution experiments were carried out at several solid/water ratios: 1/200, 1/100, and 1/75. Results indicated that MCM-41 and Al-MCM-41 are more soluble than amorphous silica at ambient temperatures. Using standard thermodynamic data, a minimum Gibbs free energy of formation of -847.9 kJ/mol for MCM-41 was calculated compared to -848.85 kJ/mol for amorphous silica and -856.3 kJ/mol for quartz. X-ray diffraction (XRD) analyses of recovered solids indicated a progressive loss of crystallinity in MCM-41 and Al-MCM-41 over the 79 day dissolution experiment. BET nitrogen surface area analyses of recovered solids revealed no appreciable change in the surface area of either material after 79 days of reaction in water. Field emission scanning electron microscope (SEM) images taken of the 79 day MCM-41 sample showed some degradation of the initial structure-fine, worm-like particles.     

Synthesis and surface modification of mesoporous mcm-41 silica materials

Surface modification offers a great opportunity to adjust both the pore diameter and surface properties of MCM-41 type organic–inorganic hybrid materials which result in materials of improved hydrothermal and mechanical stability. Therefore, MCM-41 silica, surface modified with organic ligands, are promising systems with engineered properties and attractive for advanced applications. In the present study, after optimization of the reaction conditions highly ordered MCM-41 silica spheres with uniform mesopores were prepared by the pseudomorphic transformation route. The effect of functionality and alkyl chain length of the alkyl ligands during surface modification was probed by using butyl and octylsilanes with two different functionalities. Due to steric hindrance, the longer chains are assumed to bind only on the outer silica surface and near the entrance of the pores, while the shorter chains are also able to bind to the interior mesopore walls. The resulting materials were comprehensively characterized before and after surface modification using nitrogen sorption techniques, XRD, SEM, solid-state NMR spectroscopy and FTIR spectroscopy. From chromatographic test measurements it was found that the separation power primarily depends on surface coverage and alkyl chain length. On the basis of the present data, surface modified mesoporous silica of MCM-41 type are very promising candidates for future chromatographic applications.     

Influence of cross profile of PE fibers on thermal properties of materials

Molecular sieves MCM-41 were synthesized from rice husk ash (RHA) as alternative sources of silica, called RHA MCM-41. The material was synthesized by a hydrothermal method from a gel with the molar composition 1.00 CTMABr:4.00 SiO₂:1.00 Na₂O:200.00 H₂O at 100 °C for 120 h with pH correction. The cetyltrimethylammonium bromide (CTMABr) was used as a structure template. The material was characterized by X-ray powder diffraction, FTIR, TG/DTG, and surface area determination by the BET method. The kinetics models proposed by Ozawa, Flynn–Wall, and Vyazovkin were used to determine the apparent activation energy for CTMA⁺ species decomposition from the pores of MCM-41 material. The results were compared with those obtained from the MCM-41 synthesized with silica gel. The synthesized material had specific surface area, size, and pore volume as specified by mesoporous materials developed from conventional sources of silica.     

Influence of the pore structure of MCM-41 and SBA-15 silica fibers on atomic layer chemical vapor deposition of cobalt carbonyl

Mesoporous high surface area MCM-41 and SBA-15 type silica materials with fibrous morphology were synthesized and used as support materials for the ALCVD (atomic layer chemical vapor deposition) preparation of Co/MCM-41 and Co/SBA-15 catalysts. Co/MCM-41 and Co/SBA-15 catalysts were prepared by deposition of Co2(CO)8 from the gas phase onto the surfaces of preheated support materials in a fluidized bed reactor. For both silica materials, two different kinds of preparation methods, direct deposition and a pulse deposition method, were used. Pure silica supports as well as supported cobalt catalysts were characterized by various spectroscopic (IR) and analytical (X-ray diffraction, Brunauer-Emmett-Teller, elemental analysis) methods. MCM-41 and SBA-15 fibers showed considerable ability to adsorb Co2(CO)8 from the gas phase. For MCM-41 and SBA-15 silicas, cobalt loadings of 13.7 and 12.1 wt % were obtained using the direct deposition method. The cobalt loadings increased to 23.0 and 20.7 wt % for MCM-41 and SBA-15 silicas, respectively, when the pulse deposition method was used. The reduction behavior of silica-supported cobalt catalysts was found to depend on the catalyst preparation method and on the mesoporous structure of the support material. Almost identical reduction properties of SBA-15-supported catalysts prepared by different deposition methods are explained by the structural properties of the mesoporous support and, in particular, by the chemical structure of the inner surfaces and walls of the mesopores. Pulse O2/H2 chemisorption experiments showed catalytically promising redox properties and surface stability of the prepared MCM-41- and SBA-15-supported cobalt catalysts.