钾修饰SiO2负载超低含量过渡金属催化剂上乙烷选择氧化反应

制备了一系列碱金属K修饰的S iO2负载的超低含量过渡金属(K∶M∶S i=10∶1∶1000,摩尔比,M=V、Cr、Mn、Fe、Co、N i、Cu和Zn)催化剂,考察了该系列催化剂对乙烷分子氧选择氧化生成醛类含氧化合物的反应性能.引入钾促进了S iO2负载的超低含量过渡金属催化剂上乙烷选择氧化生成乙醛和丙烯醛.钾修饰的S iO2负载超低含量过渡金属催化剂上,相对稳定的全充满、半充满或无d电子的表面离子有利于乙烷选择氧化反应进行,而存在多种价态的相对不稳定的离子结构有利于乙烷深度氧化的进行.     

担载钒氧化物催化剂对丙烷选择氧化性能

用等体积浸渍法制备了SBA-15担载的钒基氧化物催化剂,使用X射线衍射（XRD）分析、氮气吸附、紫外激光拉曼、傅里叶变换红外（FTIR）光谱和紫外-可见漫反射（UV-Vis DRS）光谱对催化剂的结构进行了表征,并评价了催化剂对丙烷选择氧化的活性与选择性.实验结果表明SBA-15载体对丙烷选择氧化的活性优于常规的SiO₂载体.SBA-15担载的低载量催化剂是高分散的催化剂体系,在低钒载量（n（V）/n（Si）<2.5%）时,催化剂具有规则的六方介孔结构.低钒载量（n（V）/n（Si）<0.1%）时,隔离四配位的钒氧化物是丙烷选择氧化生成醛类化合物的活性物种;高钒载量（n（V）/n（Si）>2.5%）时,聚合六配位的钒氧化物和微晶钒氧化物是丙烷脱氢或深度氧化的活性物种.     

丙烷选择氧化用BiCeVMoO复合氧化物催化剂中Ce组分的作用

 用X射线衍射（XRD）、激光拉曼光谱（LRS）、程序升温还原（TPR）、催化剂晶格氧反应性和微反测试等手段考察了BiCeVMoO复合氧化物催化剂的组成、结构、氧化－还原性质与催化丙烷选择氧化性能．结果表明，n（Ce）／n（Ce＋Bi）≤0．15时，Ce组分可能占据BiVMoO 结构中Bi离子所处的晶格位置．催化剂对丙烷选择氧化的催化性能与Ce组分的含量密切相关，随着Ce含量的增加，丙烯醛选择性显著升高，在n（Ce）／n（Ce＋Bi）＝0．15时达极大值．随着Ce含量的进一步增加，丙烯醛选择性下降，完全氧化产物COx选择性上升．可以认为，适量Ce组分的引入提高了催化剂晶格氧物种的反应活性，从而改善了催化剂对丙烷选择氧化的催化性能．     

丙烷选择氧化用VPO／SiO2催化剂的研究

 摘要：对比研究了VPO和VPO／SiO2催化剂的结构、表面元素氧化态、还\r\n原性及其对丙烷选择氧化反应的催化性能．与VPO催化剂相比，VPO／S\r\niO2催化剂具有较大的比表面积；VPO主要以（VO）2P2O7的形式高度分散于SiO2表面；VPO／SiO2催化剂的还原温度较低；VPO／SiO2催化剂与丙烷的相互作用较强；在反应条件下，VPO／SiO2催化剂的活性较高，但产物丙烯的选择性较低，并有丙烯醛等C3含氧化合物生成．这可能是由于VPO／SiO2催化剂表面的V与Si发生了相互作用之故．随着VPO担载量的增加，VPO／SiO2催化剂的比表面积减小；催化剂的还原温度略有升高，可还原的晶格氧量增加；催化剂表面与丙烷的相互作用增强；丙烷转化率升高而丙烯选择性降低，丙烯醛选择性在5％VPO／SiO2催化剂上最高．这可能是由于随着VPO担载量的增加，催化剂表面晶格氧的密度增大所致．     

过渡金属修饰对Pt/M-DMSN催化剂丙烷脱氢性能的影响

以两步法制备了一系列过渡金属(M=Fe, Co, Ni, Cu, Zn)修饰的树枝状介孔二氧化硅纳米粒子(DMSN)负载铂(Pt/M-DMSN)催化剂, 并对该系列催化剂进行了丙烷催化脱氢性能评价. X射线衍射(XRD)、 透射电子显微镜(TEM)、 紫外-可见漫反射光谱(UV-Vis DRS)和氢气程序升温还原(H₂-TPR)表征结果表明, 不同过渡金属在DMSN载体表面分散状态不同,且与Pt的相互作用程度不同. 其中Zn-DMSN载体最有利于Pt的分散, 且反应后催化剂上积碳含量最低; Pt/Fe-DMSN催化剂中Pt与载体的相互作用力较强. 通过活性评价结果可知, Pt/Fe-DMSN催化剂表现出最优的丙烷催化脱氢性能, 丙烷初始转化率为44.2%, 反应6 h后丙烷转化率仍可达36.5%.     

丙烯选择氧化反应中钼基催化剂动态结构的研究

 用原位共焦显微拉曼光谱技术考察了丙烷选择氧化反应中Ag－M\r\no－P－O催化剂的结构，讨论了催化剂动态结构的成因及其对催化剂性\r\n能的影响．实验结果表明，在773K和n（C3H8）∶n（O2）∶n（N2）＝\r\n3∶1∶4的反应条件下，Ag－Mo－P－O催化剂中的Mo－O物种可转化为A\r\ngMoO2PO4中的Mo－O物种（多钼酸根），此时催化剂对丙烷选择氧化具\r\n有较高的催化活性．催化剂中Mo－O物种的转化是由MoO3中Mo－O物种和\r\nAgMoO2PO4中Mo－O物种的结构特性决定的．AgMoO2PO4中的Mo－O物种具\r\n有较强的参与MarsvanKrevelen氧化－还原循环的能力，可能是丙烷选\r\n择氧化反应的活性物种．     

MoPO／SiO2催化剂上丙烷选择氧化制丙烯醛

 研究了MoPO／SiO2催化剂对丙烷选择氧化制丙烯醛的催化性能．MoO／SiO2催化剂主要表现出对丙烷氧化脱氢的催化性能，在该催化剂中添加磷后，丙烷转化率和选择氧化产物丙烯醛的选择性明显提高．催化剂的X射线衍射、拉曼光谱、程序升温还原、吡啶吸附红外光谱和程序升温脱附等表征结果表明，MoO／SiO2催化剂主要含有MoO3晶相，添加磷后，形成了表面多钼酸物种，磷以PO4四面体结构存在于表面，可能形成部分Mo—O—P键，从而抑制了MoO3在MoPO／SiO2上的形成，起到分隔活性中心的作用．在MoO／SiO2催化剂中添加磷后，催化剂的B酸和L酸酸性均增强，有利于丙烷在MoPO／SiO2催化剂表面活性的提高．由此可见，催化剂表面结构和酸性的变化可能是导致MoPO／SiO2催化性能提高的原因．     

SBA-15介孔分子筛担载的钒基氧化物催化剂对乙烷选择氧化性能

用等体积浸渍法制备了SBA-15担载的钒基(V/SBA-15)和钾修饰的钒基氧化物(K-V/SBA-15)催化剂, 使用氮气吸附、小角X射线衍射(XRD)、紫外-可见漫反射光谱(UV-Vis DRS)和紫外激光拉曼光谱对这些催化剂的结构进行表征, 并评价了这些催化剂对乙烷选择氧化的活性与选择性. 实验结果表明介孔结构SBA-15对乙烷选择氧化的活性优于常规的SiO2; 对于SBA-15担载的V/SBA-15和K-V/SBA-15催化剂, 极低钒担载量(nV:nSi≤0.1:100)时隔离的四配位钒氧化物是乙烷选择氧化生成醛类化合物的活性物种, 高钒担载量(nV:nSi≥2.5:100)时聚合的和微晶态的钒氧化物是乙烷氧化脱氢或深度氧化的活性物种.     

Te掺杂对MoPO/SiO2催化剂上丙烷选择氧化制丙烯醛反应的影响

 考察了Te的添加及Te含量对MoPO/SiO2催化剂催化丙烷选择氧化制丙烯醛反应性能的影响. MoPO/SiO2催化剂对丙烷选择氧化制丙烯醛反应的中间产物丙烯选择性较高,而Te的添加促进了丙烯向丙烯醛的转化. N2吸附、XRD、Raman、XPS、H2-TPR、丙烷脉冲、NH3-TPD和Py-IR等实验结果表明,催化剂添加Te后虽然比表面积有所下降,但单位比表面积上的酸量增加,催化剂低温可还原性得到改善,从而有利于丙烷的转化. Te可能有利于丙烯α-H的脱除和/或烯丙基的插氧反应.     

银离子修饰的介孔磷钨酸/二氧化硅催化剂氧化脱硫性能研究(英文)

采用银修饰介孔磷钨酸/二氧化硅(mesoporous HPW/SiO2)催化剂,并研究了其在模拟柴油和真实柴油氧化脱硫反应中的催化性能.通过银修饰介孔HPW/SiO2,结合银离子对有机硫化物的选择吸附性和HPW对有机硫化物的催化氧化活性,以达到选择氧化脱硫的目的.模拟柴油分别采用石油醚、苯、1-辛烯和二苯并噻吩配制,当银离子与HPW的摩尔比为2时,催化剂具有最高的选择催化氧化活性.采用N2 吸附-脱附、XRD、UV-vis和EDS表征了银修饰的介孔HPW/SiO2催化剂,结果表明,银物种分散均匀且以Ag+形式存在.真实柴油的脱硫研究表明,相比介孔HPW/SiO2催化剂,修饰的催化剂介孔Ag2-HPW/SiO2脱硫率提高了4.6%,初始硫含量为1800×10-6的直馏柴油能被脱除至228×10-6,脱硫率为87.3%.介孔Ag2-HPW/SiO2催化剂具有良好的再生性能,经再生处理后,Ag的损失量极少,其三次脱硫率达到84.8%.     

双溶剂浸渍法制备VOX/MCF催化剂及丙烷选择氧化

采用双溶剂法制备了负载型氧化钒类催化剂(VOx/MCF),N2物理吸附、X射线衍射、透射电镜、拉曼光谱、程序升温脱附、程序升温还原等系统研究了催化剂的物化性质并测试了其在丙烷选择氧化反应中的催化性能.结果表明,由双溶剂法制备的VOx/MCF催化剂具有较好的催化活性,且在氧化钒负载量基本一致的前提下,双溶剂法制备的VOx/MCF催化剂比普通浸渍法制备的VOx/MCF具有更高的催化活性,这与双溶剂法的制备过程可以使得钒物种尽可能进入载体内表面,有利于氧化钒的较好分散有关,而高度分散的氧化钒物种,正是丙烷选择氧化反应的活性中心.     

丙烷选择氧化制丙烯醛MoVTeO/SiO2催化剂结构与性能研究

考察了MoVTeO/SiO₂系列催化剂对丙烷选择氧化制丙烯醛反应的催化性能,结合XRD,Raman和TPD等表征结果研究了催化剂结构、表面性质与催化性能之间的关系.结果表明,以Mo为主要活性组分的催化剂(MoV_0.2Te_0.1/SiO₂)具有较好的催化性能.在V,Te组分存在下,Mo物种的分散度和MoO₃的可还原性能提高.以表面钼酸盐和多钼酸盐类形态存在的高分散Mo物种有助于提高催化活性,而催化剂较弱的表面酸性对丙烯醛的生成有利.     

Key aspects of crystalline Mo-V-O-based catalysts active in the selective oxidation of propane

Mo-V-O-based complex metal oxide catalysts were synthesized hydrothermally for the first time, characterized structurally and tested in the selective oxidation of propane to acrylic acid, and the results obtained were compared on the basis of catalyst crystal structures in order to clarify key aspects of alkane selective oxidation over multifunctional metal oxide catalysts. The catalysts tested were black solids of rod-shaped crystals, which had a layer structure in the direction of fiber axis and various high dimensional arrangements of metal octahedra in the cross-section plane. A strong dependency on the octahedra arrangements and a facet dependency were observed, and the roles of metal elements in the course of selective oxidation of propane were clarified by comparing the catalytic performance of various Mo-V-O-based catalysts. We discuss the multi-functional character derived from high dimensional structures of the catalysts and mechanism of the selective oxidation of propane.     

Highly Dense Isolated Metal Atom Catalytic Sites: Dynamic Formation and In Situ Observations

Atomically dispersed noble‐metal catalysts with highly dense active sites are promising materials with which to maximise metal efficiency and to enhance catalytic performance; however, their fabrication remains challenging because metal atoms are prone to sintering, especially at a high metal loading. A dynamic process of formation of isolated metal atom catalytic sites on the surface of the support, which was achieved starting from silver nanoparticles by using a thermal surface‐mediated diffusion method, was observed directly by using in situ electron microscopy and in situ synchrotron X‐ray diffraction. A combination of electron microscopy images with X‐ray absorption spectra demonstrated that the silver atoms were anchored on five‐fold oxygen‐terminated cavities on the surface of the support to form highly dense isolated metal active sites, leading to excellent reactivity in catalytic oxidation at low temperature. This work provides a general strategy for designing atomically dispersed noble‐metal catalysts with highly dense active sites.     

有序多孔过渡金属氧化物及其负载贵金属催化剂对挥发性有机物氧化的催化性能

大部分的挥发性有机物(VOCs)污染环境,危害人身健康.目前,我国虽然已开展了治理 VOCs污染的工作,但还缺乏有效的、拥有自主知识产权的 VOCs治理技术,因此研发新型高效 VOCs处理技术迫在眉睫.催化氧化法是公认的最有效消除 VOCs的途径之一,而高性能催化剂的研发是实现该过程的关键.近年来,人们围绕消除 VOCs的高效且价廉的催化剂的研发开展了卓有成效的工作,许多过渡金属氧化物、混合或复合金属氧化物及其负载贵金属催化剂均被认为是有效的催化氧化材料.与体相材料相比,多孔材料具有发达的孔道结构和高的比表面积,一方面有利于反应物的扩散、吸附和脱附,因而具有更高的催化活性和选择性;另一方面有利于活性组分(如贵金属等)在多孔材料表面的高分散,抑制活性组分的烧结,因而具有更好的催化稳定性.本文简述了近年来多孔金属氧化物在环境污染物消除领域的研究进展,阐述了以有序介孔或大孔过渡金属氧化物、钙钛矿型氧化物和负载贵金属催化剂的制备及其对典型 VOCs(如苯系物、醇类、醛类及酮类等)氧化的催化性能,重点介绍了四类催化材料,包括有序介孔过渡金属氧化物或复合氧化物(Co3O4, MnO2, Fe2O3, Cr2O3和 LaFeO3等)催化剂,有序介孔金属氧化物负载贵金属(Au/Co3O4, Au/MnO2和 Pd/Co3O4等)催化剂,三维有序大孔过渡金属氧化物或复合氧化物(Fe2O3, LaMnO3, La0.6Sr0.4MnO3和 La2CuO4等)催化剂,以及三维有序大孔金属氧化物负载贵金属(Au/Co3O4, Au/LaCoO3, Au/La0.6Sr0.4MnO3和 AuPd/Co3O4等)催化剂的制备及其物化性质与对苯、甲苯、二甲苯、乙醇、丙酮、甲醛、甲烷或氯甲烷等 VOCs氧化的催化性能之间的相关性.借助二氧化硅或聚甲基丙烯酸甲酯微球等硬模板,采用纳米浇铸法可制备出二维或三维的有序单一或多级孔道结构的金属氧化物.研究表明,多孔金属氧化物的催化性能远优于其体相甚至纳米催化剂的.有序多孔材料的优异催化性能与其拥有大的比表面积、高的吸附氧物种浓度、优良的低温还原性、独特的孔道结构、活性组分的高分散以及贵金属与氧化物载体之间的强相互作用等有关.探明影响催化剂活性的因素有利于从原子水平上认识催化过程,为新型高效催化剂的设计与制备奠定基础.本文还指出了此类研究中存在的一些问题,例如利用硬模板法制备多孔材料的缺点是目标催化剂的收率低,硬模板浪费严重,大规模制备多孔催化剂势必增加制备成本,这些问题有待于妥善解决.与此同时,还展望了 VOCs消除技术的未来发展趋势,采用多种技术联用的方法有望最大程度地提高 VOCs的消除效率.     

Key aspects of crystalline Mo-V-O-based catalysts active in the selective oxidation of propane

Mo-V-O-based complex metal oxide catalysts were synthesized hydrothermally for the first time, characterized structurally and tested in the selective oxidation of propane to acrylic acid, and the results obtained were compared on the basis of catalyst crystal structures in order to clarify key aspects of alkane selective oxidation over multifunctional metal oxide catalysts. The catalysts tested were black solids of rod-shaped crystals, which had a layer structure in the direction of fiber axis and various high dimensional arrangements of metal octahedra in the cross-section plane. A strong dependency on the octahedra arrangements and a facet dependency were observed, and the roles of metal elements in the course of selective oxidation of propane were clarified by comparing the catalytic performance of various Mo-V-O-based catalysts. We discuss the multi-functional character derived from high dimensional structures of the catalysts and mechanism of the selective oxidation of propane.     

Selective oxidation of hydrocarbons catalyzed by iron-containing heterogeneous catalysts

Recent studies on iron-based heterogeneous catalysts for selective oxidation of hydrocarbons are reviewed with emphasis on the partial oxidation of methane and the epoxidation of alkenes. High dispersion of iron sites is essentially important for the selective oxidations. The effective catalysts include immobilized or encapsulated iron complexes, iron-doped metal oxides such as Fe³⁺-doped silica, iron-containing microporous and mesoporous materials, and iron-containing compounds with isolated iron sites typified by iron phosphate. The structure-reactivity relationships and the factors affecting the catalytic performances are discussed with the aim to uncover the requirements of the active iron sites in target-selective oxidation.     

Selective oxidation of hydrocarbons catalyzed by iron-containing heterogeneous catalysts

Recent studies on iron-based heterogeneous catalysts for selective oxidation of hydrocarbons are reviewed with emphasis on the partial oxidation of methane and the epoxidation of alkenes. High dispersion of iron sites is essentially important for the selective oxidations. The effective catalysts include immobilized or encapsulated iron complexes, iron-doped metal oxides such as Fe³⁺-doped silica, iron-containing microporous and mesoporous materials, and iron-containing compounds with isolated iron sites typified by iron phosphate. The structure-reactivity relationships and the factors affecting the catalytic performances are discussed with the aim to uncover the requirements of the active iron sites in target-selective oxidation.     

A study of the surface region of the Mo-V-Te-O catalysts for propane oxidation to acrylic acid

The bulk mixed Mo-V-Te oxides possess high activity and selectivity in propane oxidation to acrylic acid and represent well-defined model catalysts for studies of the surface molecular structure-activity/selectivity relationships in this selective oxidation reaction. The elemental compositions, metal oxidation states, and catalytic functions of V, Mo, and Te in the surface region of the model Mo-V-Te-O system were examined employing low energy ion scattering (LEIS) and X-ray photoelectron spectroscopy (XPS). This study indicated that the surfaces of these catalysts are terminated with a monolayer, which possesses a different elemental composition from that of the bulk. The rates of propane consumption and formation of propylene and acrylic acid depended on the topmost surface V concentration, whereas no dependence of these reaction rates on either the surface Mo or Te concentrations was observed. These findings suggested that the bulk Mo-V-Te-O structure may function as a support for the unique active and selective surface monolayer in propane oxidation to acrylic acid. The results of this study have important practical consequences for the development of improved selective oxidation catalysts by introducing surface metal oxide components to form new surface active V-O-M sites for propane oxidation to acrylic acid.