活性炭担载的Rh-M0-K合成醇催化剂

采用XRD、EXAFS等技术研究微量贵金属Rh对活性炭担载的Rh-Mo-K合成醇催化剂结构的影响,并关联其催化性能.氧化态Rh-Mo-K/AC样品中Rh与Mo有着较强的相互作用,使得K2Mo2O7向MoO2转化.硫化还原后,Mo主要以MoS2微晶形式存在,其有序结构尺度随Rh含量的增加而减小.经Rh助剂修饰后,催化剂的合成醇催化性能有明显的提高.     

NiMo 催化剂上MoS2 形貌与其DBT 加氢脱硫选择性的关系

制备了两个系列不同镍钼负载量的NiMo 催化剂,并用X 衍射、N2 物理吸附和透射电镜进行了表征。以二苯并噻吩
为模型硫化物,在高压固定床微型反应器上对该NiMo 催化剂的加氢脱硫性能进行了评价,研究了MoS2 形貌与催化剂加氢脱
硫选择性之间的关系。结果表明,镍钼负载量对MoS2 形貌有明显的影响。Mo18Ni4 催化剂(含18% MoO3 和4% NiO)上
MoS2 呈多级层状结构,具有较高的加氢脱硫活性和优异的加氢脱硫选择性。加氢选择性与催化剂上活性组分MoS2 的堆积层
数相关联呈很好的线性关系;堆积层数越多,其加氢选择性也越高。     

γ-Mo2N和分子筛负载的钼氮化物的结构表征

采用程序升温氮化的方法制备了分子筛负载的钼氮化物催化剂,并用EXAFS方法研究了 氮化前后Mo原子的局域配位情况.氮化前负载MoO3样品的径向结构函数中有三个峰,其中前两 个峰对应着最近的Mo-O配位壳层,但是第一个峰与第二个峰的比例比晶体MoO3中的比例大很 多,表明分子筛负载的MoO3具有更紧密的结构.氮化以后,Mo2N样品的径向结构函数中有三个 峰,对应于一个Mo-N和两个Mo-Mo配位壳层,与面心立方模型符合得很好.根据XRD和EXAFS谱 的计算表明,Mo2N中的N原子使Mo-Mo键拉长并削弱.分子筛负载的Mo2N样品具有与非负载Mo2 N样品近似相同的径向结构函数,只是对应于Mo-N壳层的峰较弱,表明负载的Mo2N具有更大的 结构无序性.     

负载型TiO2-Al2O3复合载体在超深度加氢脱硫中的应用

运用HRTEM、FT-Raman、TPR等方法表征了Mo活性组分在负载型TiO2-Al2O3复合载体和Al2O3上不同形态和性质。比较了TiO2-Al2O3复合载体同传统Al2O3载体对CoMo催化剂结构的影响,并以4,6-二甲基二苯并噻吩（4,6-DMDBT）为探针考察了催化剂的超深度加氢脱硫（UHDS）性能。结果表明,在负载型TiO2-Al2O3复合载体中, MoO3同载体之间的相互作用较弱,这种弱的相互作用使MoO3更多的以八面体配位Mo物种（MoⅥ）及其二维的聚合物的形式存在。二维聚合物有利于形成具有更高活性的多层MoS2结构,明显提高催化剂的超深度加氢脱硫催化活性。     

Pd-Mo-K/Al2O3催化剂的结构及合成醇性能

采用 XRD、EXAFS 技术研究了不同Pd含量的 Pd-Mo-K/Al2O3 催化剂结构,并关联其合成低碳混合醇性能。结果表明,在氧化态 Mo-K/Al2O3 催化剂体系中添加 Pd后,“K-Mo”物相晶粒变小,分散度提高,说明钯可能和钾钼物种发生了较强的相互作用。经硫化还原处理后,发生了氧硫交换,钼主要以MoS2物种形式存在,其粒度随着Pd含量的增加而明显减小。尺寸的显著变化可能导致MoS2与载体作用形式的改变,从而影响CO加氢催化反应的性能。在硫化态催化剂中,Pd的添加不仅能提高CO加氢合成醇的收率和选择性,而且有利于改善产物的分布。基于以上结果,认为“K-Mo”作用物种和Pd物种均为合成醇的催化活性组份,它们间的相互协同作用使催化剂性能得到显著改善。     

硫化态PtMo/γ-Al2O3催化剂活性位的低温CO-FTIR方法表征及噻吩HDS活性的研究

目前, 负载型钼(钨)基双组元过渡金属硫化物[Co(Ni)Mo(W)/γ-Al2O3]被广泛应用于石油馏分油的加氢脱硫(HDS)和加氢脱氮(HDN)反应过程[1～3]. 许多研究结果表明, 硫化态Co(Ni)Mo(W)/γ-Al2O3催化剂的活性相组元钴(镍)、钼(钨)及硫形成具有二维六方点阵结构的Co(Ni)-Mo(W)-S相(slab). 其中钴(镍)和钼(钨)的主要催化功能依次是活化H2和锚定杂原子有机底物[3～5].     

加氢脱氮催化剂中硫化钼结构的表征

众所周知,重油加氢脱氮(HDN)所用Mo-Ni/Al2O3催化剂需经预硫化后始有显著的活性,关于硫化的条件工业上已较成熟,但在持续反应过程中硫化催化剂的结构与活性间的关系则很复杂,如硫化钼的价态和结构、金属组分和担体间的相互作用、反应条件及原料对催化剂组分的影响,以及硫化态催化剂中MoS2结晶的形貌等都可以引起催化剂活性本质的变化.     

Al2O3性质对加氢脱硫催化剂Co-Mo/Al2O3活性相形成的影响

以两种商用Al2O3为载体,制备了汽油选择性加氢脱硫催化剂Co-Mo/Al2O3,并采用红外光谱、X射线衍射、N2吸附-脱附、透射电镜、扫描透射-能谱和X射线光电子能谱等手段系统研究了载体物化性质对催化剂活性相形成的影响.结果表明,表面羟基数量少和结晶程度高的载体与活性金属间相互作用减弱,促进了Mo物种的硫化还原,使MoS2片晶的尺寸和层数增加,且其硫化态催化剂上CoMoS活性位更多,CoMoS/MoS2比更大,因而显著提高了相应Co-Mo催化剂加氢脱硫活性和选择性.     

不同助剂的硫化MoO3／ZrO2催化剂上CO加氢合成低碳混合醇的反应性能

研究了碱金属离子（Li^ 、Na^ 、K^ 、Cs^ ）和碱土金属离子（Ca^2 、Sr^2 、Ba^2 ）为助剂的硫化MoO3/ZrO2催化剂上CO加氢合成低碳混合醇的反应性。碱金属离子（Li^ ,K^ )、特别是钾离子为助剂的催化剂比之碱土金属离子助剂具有 更好的合成低碳醇的活性和选择性。从一系列的实验和分析发现，硫化K－MoO3/ZrO2的合 成低碳醇的活性和选择性强烈依赖于钾助剂的含量和反应条件。合理 选择 最佳K／Mo比（－0.5原子比）、反应压力、温度和空速可以获得较好的合成醇活性和选择性。     

钼(钨)-钼-硫簇合物的~(95)Mo NMR研究

对含有[MS4]2-（M＝Mo，W）单元的一系列钼（钨）-钼-硫簇合物进行了95MoNMR研究，定性分析了95Mo化学位移随金属原子配位数、配位金属种类和配位金属配体改变而变化的规律。结果表明，随着[MoS4]2-配位金属原子数的增加，[MoS4]2-上Mo的化学位移逐渐向高场移动，这可归因于低氧化态MO0上的电子通过硫桥离域到高氧化态的Mo上。为了解析Mo0上化学位移的实验结果，采用MM＋力场对[（OC）4MOS2MoS2]2-和[｛（OC）4Mo｝MoS4]2-的晶体结构进行几何优化，使之更接近于溶液中的结构，然后利用Fenske－Hall方法计算Mo原子上的净电荷分布，计算结果较好地好择了Mo和Mo0化学位移的变化趋势。     

硫化态Co—Mo—K／AC合成醇催化剂的EXAFS研究

采用XRD,EXAFS等手段考察了Co载量对催化剂结构的影响,并关联其合成醇活性,活性炭担载的硫化态Co-Mo-K样品中,Mo主要以MoS2物种形式存在于活性炭的表面上,而Co在低Co载量时主要形成 “Co-Mo-S”相,在高Co负载量会有部分类Co9S8的物相出现,经Co助剂修饰后的催化剂显示出良好的合成醇 化性能,CO助剂有利于合成C2醇,Co/Mo原子比为0．5时,表面“Co-Mo-S”相可能达到饱和,合成醇的收率也最高,Co物种是和MoS2物相以协同的方式起作用的。     

Co-K-Mo/γ-Al2O3催化剂的合成低碳醇性能及其结构研究

氧化态Ｋ－ＭｏＯ３／γ－Ａｌ２Ｏ３催化剂中添加Ｃｏ（ＮＯ３）２后在空气中四个不同温度下焙烧再硫化,制得Ｃｏ－Ｋ－ＭｏＯ３／γＡｌ２Ｏ３催化剂,对其ＣＯ加氢合成低碳醇的催化反应性能进行了评价,运用ＸＲＤ,ＬＲＳ及ＥＸＡＦＳ等手段对催化剂及其氧化态前躯体的结构进行了表征,活性测试结果表明加Ｃｏ后于５００－６５０℃焙烧制得的催化剂活性较高,且使Ｃ２＋醇比例增加,结构分析结果显示加Ｃｏ后３５０℃焙烧时,Ｃ     

XPS Characterization of Carbon Nanotube Supported CoMo Hydrodesulfurization Catalysts

In this paper, the effect of catalytic support and sulfiding method on the chemical state of supported Co-Mo catalysts is studied by XPS. After sulfidation with in-situ method, the majority of molybdenum in CNT supported CoMo catalyst is transferred to a species with a formal chemical state Mo(Ⅳ) in MoS2 phase, and the rest to Mo(Ⅴ) which consists of Mo coordinated both to O and S, such as MoO2S2^2- and MoO3S^2-. In case of CoMo/γ-Al2O3 catalyst sulfided with in-situ method, a fraction of molybdenum is transferred to formal state Mo(Ⅳ) in the form of MoS2, but there is still a mount of unreduced Mo(VI) phase which is difficult to be sulfided. In CoMo/CNT catalyric system sulfided with ex-situ method, Mo(IV) in the form of MoS2 is detected along with a portion of unreduced Mo(VI) phase, suggesting that not all the Mo phases are reduced and sulfided by ex-situ method. As for CoMo/γ-Al2O3, a portion of molybdenum is sulfided to intermediate reduced state Mo(V) which consists of Mo coordinated both to O and S, such as MoO2S2^2- and MoO3S^2-, in addition, there is still a fraction of unreduced Mo(Ⅵ)phase. XPS analyses results suggest that CNT support facilitates the reduction and sulfidation of active species to a large extent, and that alumina support strongly interacts with active species, hereby producing a fraction of phase which resists complete sulfiding. Catalytic measurements of catalysts in the HDS of dibenzothiophene (DBT) show that CoMo/CNT catalysts are of higher HDS activity and selectivity than CoMo/γ-Al2O3 catalyst, which is in good relation with the sulfiding behavior of the corresponding catalyst.     

硫化态三组元NiMoP/γ-Al2O3催化剂的TPR表征及噻吩HDS活性的研究

A series of sulfided tertiary NiMoP/γ-Al2O3 catalysts with different contents of MoO3 were prepared by using molybdophosphoric acid of Keggin structure(H3PMo12O40) and nickel nitrate as origins of active phase components of molybdenum, phosphorus and nickel, and characterized by TPR technique, with their HDS activity being investigated with thiophene as a model substrate. For the sulfided Mo-0 catalyst containing no nickel as promoter, the only hydrogen sulfide evolution peak Ⅰ　is observed at 462 K and attributed to the hydrogenation of the so-called edge sulfur atoms chemisorbed on coordinatively unsaturated(cus) Mox+ sites on the MoS2 phase(MoS2 slab). With the introduction of nickel into the active phase of the sulfided Mo-0 catalyst and with the increase of the molybdenum loading, a new hydrogen sulfide evolution peak Ⅱ gradually develops at the low temperature side of the peak Ⅰ, at the same time accompanied by both the increase of the area ratio of the peak Ⅱ to the peak Ⅰ and the shift of the hydrogen sulfide evolution maximum rate to lower temperatures, which may imply the existence of two kinds of active centers related to molybdenum and nickel respectively and the synergic action between the two centers above. It should be noted that for the sulfided NiMoP/γ-Al2O3 catalysts, the thiophene HDS rate and the quantity of hydrogen sulfide evolved during TPR process increase monotonously with the atomic ratio of molybdenum to nickel in the form of ［n(Ni)+n(Mo)］/n(Ni). On the basis of the results here, the conclusion may be reached that the two kinds of vacancies can be formed on the edge of Ni-Mo-S slab due to the loss of S during TPR process and vacancies or sites related to the H2S evolution peak II should be regarded as the mainly active reaction centers of thiophene HDS.     

Characterization by 27Al NMR, X-ray absorption spectroscopy, and density functional theory techniques of the species responsible for benzene hydrogenation in Y zeolite-supported carburized molybdenum catalysts

Carburized molybdenum catalysts supported on a dealuminated NaH-Y zeolite were prepared by carburization under a 20% methane in hydrogen flow of two precursors obtained by adsorption of molybdenum hexacarbonyl, one containing 5 wt % and the other 10 wt % Mo, and a third one was prepared by impregnation with aqueous ammonium heptamolybdate, containing 5 wt % Mo. The three catalysts displayed very distinct behaviors in the benzene hydrogenation reaction at atmospheric pressure and 363 K. By using XANES spectroscopy at the molybdenum L edge, EXAFS and XANES spectroscopy at the molybdenum K edge, and 27Al solid-state NMR spectroscopy, it was shown that different carburized molybdenum species exist in each sample. In the catalyst containing 10 wt % Mo, formation of molybdenum carbide nanoparticles was observed, with an estimated diameter of 1.8 nm. In the catalyst containing 5 wt % Mo and prepared by carburization of adsorbed molybdenum hexacarbonyl, formation of molybdenum oxycarbide dimers is proposed. In the latter case, density functional theory calculations have led to a dimer structure which is compatible with EXAFS results. In the catalyst prepared by impregnation with ammonium heptamolybdate solution followed by carburization, the molybdenum seems to interact with extraframework alumina to produce highly disordered mixed molybdenum-aluminum oxycarbides.     

Characterization of active sites over reduced Ni-Mo/Al(2)O(3) catalysts for hydrogenation of linear aldehydes

Reduced Ni-Mo/Al(2)O(3) catalysts exhibit a behavior analogous to that of sulfided Ni-Mo/Al(2)O(3) catalysts in hydrogenation of linear aldehydes to alcohols. Similar to what has been previously reported for sulfided catalysts, NO and CO(2) can be used over the reduced Ni-Mo catalysts as probe molecules for the active sites responsible for two competing reactions -- aldehyde hydrogenation to alcohols and condensation reactions to heavy products, respectively. Reduced catalysts have a higher aldehyde conversion activity and alcohol selectivity than their sulfided counterparts. The reduction temperature has a strong effect on the surface density of anion vacancies, which are responsible for alcohol formation. Reduction temperature also plays a role in determining the abundance of OH groups on the alumina surface. The effect of reduction temperature also manifests itself through the differences seen in the oxidation states of Mo and Ni species.     

EFFECTS OF SYNTHESIS PARAMETERS ON ZEOLITE ZSM-48 IN A SOLID REACTION MIXTURE SYSTEM

IntroduCtionReCently,zcoliteZSM-48hasbeenspehesizedinapurelysolidsystemll1.Thismethedusedtosynthesizezcolitescangndlyincreasetheyieldofpnductsperunitvolume,simplifythepr0cedresanddecreasethecnvironmentalpolluti0n.ThisincreasestheacualPOssibilityofsynthesisofhigh-silicazcolitesinchemicalindustry.MoreOver,itisalsohelpfulforstUdyingthezeolitecrystalliZai0nmechanism.ItiswellknownthatthesamewneofzeolitessynthesizedindifferentsystemshasdifferentcatalyticpropertiesduetothechangesoftheirfinestruC…