Enhancing Isolated Ti（ Ⅳ ） Framework Sites in HMS

IntroductionTitanium modified mesoporous molecular sieves,such as Ti-MCM-41[1—4], Ti-HMS[5], Ti-SBA15[6, 7], and their catalytic performances havebeen investigated. Framework substitution and graftingtechniques have been employed for the preparation ofti…     

Au/N-Ti-HMS的制备及其催化丙烯直接环氧化反应的研究

以十二胺为模板剂合成了一系列不同Ti含量的介孔分子筛Ti-HMS,并通过高温氨处理对其进行高温改性,在分子筛表面和骨架中引入碱性N原子.分别以改性前后的Ti-HMS为载体使用沉积沉淀法制得纳米金催化剂,并考察氢气、氧气共存条件下催化丙烯气相直接环氧化的催化性能.通过氮气等温吸附-脱附、X射线衍射(XRD)、傅里叶变换红...     

Enhancing Isolated Ti(Ⅳ) Framework Sites in HMS

Ti-HMS materials were prepared by grafting titanocene onto the inner walls of hexagonal mesoporous silica (HMS). The materials were characterized via powder X-ray diffraction, N2 adsorption-desorption isotherms, diffuse reflectance UV-Vis spectroscopy, and thermo-gravimetric analysis. The template of HMS was removed by calcination,ethanol-extraction, and ethanol-extraction followed by hydrolysis. The available grafting sites of OH groups depend on the different template removal methods of HMS. Ethanol-extraction followed by hydrolysis favors site-isolated Ti atoms in HMS. The catalytic performances of Ti-HMS materials were tested in the oxidation of 4-tert-butyltoluene with aqueous hydrogen peroxide. Ti-HMS prepared from HMS via the processing of ethanol-extraction followed by hydrolysis as support gave a maximum conversion of 7. 5% and a complete selectivity to 4-tert-butyl-benzaldehyde, and showed a higher activity compared with those prepared by calcination and ethanol-extraction.     

新型高疏水性富含甲基Ti-HMS介孔分子筛的制备、表征和催化性能

通过共缩合和气相甲基接枝两步法制备了新型的高疏水性富含甲基的Ti-HMS介孔分子筛.采用X光衍射、N2吸附、红外光谱、硅核磁、热重、元素分析(原子发射光谱)、紫外可见光谱等手段和亲水性实验对样品进行表征,并用环己烯环氧化反应进行催化性能测试.结果表明,经过两步接枝甲基后,Ti-HMS仍保持典型的介孔结构特征,拥有较多的甲基含量和较高的疏水性,催化环己烯环氧化活性和选择性均比共缩合法(一步接枝法)Ti-HMS有所提高.     

Ti-HMS分子筛的合成与表征

 以十二胺(DDA)为模板剂,采用室温晶化合成了钛硅中孔分子筛Ti-HMS,并用XRD,IR,UV-Vis和N2吸附对分子筛样品进行了表征,考察了配料硅/钛比、模板剂用量及晶化时间对合成分子筛的影响. 结果表明,Ti-HMS分子筛具有较大的比表面,孔径约为3 nm. 随着配料硅/钛比的降低,Ti-HMS分子筛的比表面积减小,进入骨架的钛量增多,且非骨架钛也增多. n(DDA)/n(SiO2)≤0.22时,随着模板剂用量的减少,Ti-HMS分子筛的结晶度下降,骨架钛含量减少,非骨架钛含量增加. 晶化时间在9~18 h最佳.     

Ti-HMS催化氧化脱除模拟燃料中的硫化物

 将噻吩、苯并噻吩、二苯并噻吩和4,6-二甲基二苯并噻吩(DMDBT)分别溶于正辛烷配成模拟燃料,以Ti-HMS为催化剂,以H2O2为氧化剂,对模拟燃料的氧化脱硫进行了研究,考察了Ti-HMS的催化活性及硅/钛比和结晶度对催化剂活性的影响. 结果表明,在Ti-HMS上硫化物氧化的难易顺序是由噻吩环上硫原子的电子云密度和硫化物分子的空间位阻共同决定的; 氧化反应发生在分子筛孔道内,骨架钛原子为活性中心; DMDBT在Ti-HMS上的氧化脱除效果比在TS-1,Ti-β或Ti-MCM-41上好. 随着Ti-HMS中硅/钛比的增大,DMDBT的脱除率降低; 随着Ti-HMS分子筛结晶度的升高,DMDBT的脱除率升高.     

钛硅分子筛催化1-丁烯环氧化研究

自1983年Taramasso等报导TS-1的合成以来,钛硅分子筛的合成及应用一直是分子筛催化领域的热点。经典TS-1合成方法采用四丙基氢氧化铵（TPAOH）为模板剂,合成成本较高、条件苛刻,限制了其应用。用四丙基溴化铵（TPABr）为模板剂代替TPAOH,能够成功地合成TS-1。不同孔道结构的钛硅分子筛,如Ti-β、Ti-MCM-41、Ti-HMS等弥补了TS-1较小孔径的缺点,进一步扩大了钛硅分子筛的应用。本文以不同合成方法得到的TS-1及中孔Ti—HMS为催化剂,双氧水为氧化剂,1-丁烯环氧化合成1,2-环氧丁烷,研究了不同钛硅分子筛对1-丁烯环氧化反应的催化性能。     

Oxidative desulfurization of model diesel oil over Ti-containing molecular sieves using hydrogen peroxide

Three Ti-containing molecular sieves were studied in the oxidative desulfurization (ODS) of model diesel oil with hydrogen peroxide. Under optimal conditions, dibenzothiophene (DBT) conversion up to 80.6% and 42.6% could be obtained with Ti-HMS and Ti-MSU as catalysts, respectively. However, there is no activity in the sulfoxidation of DBT over TS-1. Effects of the TiO₂/SiO₂ ratio in Ti-HMS and reaction conditions, such as the reaction temperature, reaction time, n(H₂O₂)/n(S) on the sulfur removal were investigated.     

直链烷烃对Ti-HMS分子筛合成的影响

以十二胺为模板剂,正硅酸乙酯为硅源,钛酸四丁酯为钛源,直链烷烃正己烷或正辛烷为有机添加剂,在室温下合成出具有较大孔径的Ti-HMS分子筛.研究了烷烃对Ti-HMS分子筛的扩孔作用及对分子筛结晶度和催化性能的影响.结果表明,加入的烷烃越多,分子筛的孔径越大;烷烃链长越长,对Ti-HMS的扩孔作用越显著.与不加烷烃的Ti-HMS相比,加入烷烃后,分子筛的结晶度及四配位骨架钛的含量均有所降低,而且加入的烷烃量越多,影响越明显.将加入烷烃所得的Ti-HMS用于模拟燃料中4,6-二甲基二苯并噻吩的氧化脱除反应,结果发现,Ti-HMS的催化氧化活性有所提高,对4,6-二甲基二苯并噻吩的脱除速率增大.     

Characterization and catalytic performance of methyl-grafted Ti-HMS catalysts prepared by the CVD method

Methyl-grafted Ti-HMS catalysts were prepared by the chemical vapor deposition (CVD) method using TiCl₄ as titanium source and various organic silanes as silylating agents. The catalysts were characterized by XRD, N₂-adsorption-desorption, FTIR, ²⁹Si NMR, TGA, DR UV-vis, and evaluated by the epoxidation of propylene using cumene hydroperoxide (CHP) as oxidant. The results reveal that the silylated Ti-HMS catalysts are more active than the unsilylated Ti-HMS catalyst, and the methyl-grafted Ti-HMS catalyst silylated with hexamethyldisilazane (HMDSZ) exhibits better epoxidation performance than the analogues silylated with trimethylchlorosilane (TMCS) or dimethyldichorosilane (DMDCS). It is proposed that not only the form of T-O-SiMe_n (n = 2 or 3) but also the breakage of Ti-O-T (Si-O-Si or Si-O-Ti) are observed in silylation using Cl-containing silylating agents (TMCS or DMDCS), which decrease the hydrophobicity of Ti-HMS catalysts and destroy the tetracoordinated titanium species that responsible for the epoxidation performance. This phenomenon has not been observed in silylation with HMDSZ.