添加Ru的Mo/HZSM-5催化体系上的甲烷无氧脱氢芳构化

研究了在Ｍｏ／ＨＺＳＭ－５催化剂中添加过渡金属阳离子以改变催化剂的反应性能，提高甲烷无氧脱氢芳构化的反应活性和稳定性，在添加第二组分的催化剂中，Ｍｏ－Ｒｕ／ＨＺＳＭ－５具有最佳的反应活性和稳定性，Ｒｕ的加使甲烷的转化率上原来的６％－７％提高以９．８％，采用比表面积及孔分布测定，Ｘ射线衍射，程序升温还原，程序升温氨脱附和差热分析等表征方法研究了Ｍｏ－Ｒｕ／ＨＺＳＭ－５催化剂的物理化学性质，结果表明，     

添加Ru的Mo/HZSM-5催化体系上的甲烷无氧脱氢芳构化

研究了在Ｍｏ／ＨＺＳＭ５催化剂中添加过渡金属阳离子以改变催化剂的反应性能，提高甲烷无氧脱氢芳构化的反应活性和稳定性．在添加第二组分的催化剂中，ＭｏＲｕ／ＨＺＳＭ５具有最佳的反应活性和稳定性．Ｒｕ的加入使甲烷的转化率由原来的６％～７％提高到９８％．采用比表面积及孔分布测定，Ｘ射线衍射，程序升温还原，程序升温氨脱附和差热分析等表征方法研究了ＭｏＲｕ／ＨＺＳＭ５催化剂的物理化学性质．结果表明，Ｒｕ的加入引起Ｍｏ／ＨＺＳＭ５催化剂强酸酸量的下降，并促进了Ｍｏ物种的还原．     

负载型钼基催化剂上甲烷,乙烷无氧芳构化反应研究

研究了不同载体钼基催化剂上甲烷，乙烷的无氧芳构化反应。在所采用的载体中，ＨＺＳＭ－５具有最佳性能，对甲烷的芳构化反应，Ｍｏ／ＨＺＳＭ－５催化剂表现出较高的活性和芳烃选择性；而Ｍｏ／Ａｌ２Ｏ３或Ｍｏ／ＳｉＯ２催化剂则相对较差。对于乙烷的反应，钼物种的存在更有利于甲烷或乙烯的生成，芳烃选择性相对较低。钼物种较强的断键能力可能是使甲烷Ｃ－Ｈ键活化的原因。     

甲烷在MoO_3／HZSM－5分子筛催化剂上的非氧催化转化

研究了反应温度、空速、Ｍｏ担载量和焙烧温度对ＭｏＯ３／ＨＺＳＭ－５催化剂上甲烷的芳构化反应的影响．ＨＺＳＭ－５分子筛的Ｂｒｏｎｓｔｅｄ酸性、孔道结构和Ｍｏ在分子筛中的分布是影响催化性能的重要因素．ＨＺＳＭ－５上Ｍｏ担载量为２～３％时活性最佳，在１０１３Ｋ反应温度下甲烷转化率可达９％，芳烃选择性大于９０％．空速影响的实验表明乙烯是反应的初始产物．在此基础上提出了＂甲烷酸助异裂活化＂的新概念、＂金属钼类碳烯中间物＂的新观点和甲烷芳构化的可能机理．     

27Al和29Si MAS-NMR对Mo/HZSM-5催化剂的研究

使用＾２９Ａｌ固体离分辨核磁技术对甲烷无氧芳构化催化剂Ｍｏ／ＨＺＳＭ－５分子筛进行了研究，发现ＨＺＳＭ－５分子筛本体中仅含有少量非骨架Ａｌ，Ｍｏ物种与分子筛骨架Ａｌ的相互作用随Ｍｏ担载量以及焙烧的温度的升高而增加，在高温焙烧下，Ｍｏ物种会使分子筛骨架严重脱铝，并且生成Ａｌ２（ＭｏＯ４）３新相，最终导致分子筛骨架塌陷，催化性能下降。     

处理条件对Mo/HZSM-5催化剂结构及性能的影响

使用付立叶变换红外光谱和固体高分辨核磁技术，考察了在不同处理条件下，甲烷无氧芳构化催化剂Ｍｏ／ＨＺＳＭ５分子筛骨架结构的变化情况．结果显示，较高的焙烧温度和较高的预处理温度，都会造成催化剂中担载的钼物种对分子筛骨架铝的严重抽提，特别是在钼物种含量较高时，这种情况更明显．以不同担体及不同钼物种构成的前驱态催化剂的催化反应评价结果表明，以微晶状态存在的ＭｏＯ３和与担体间以相对较弱作用力存在的高分散钼物种，在反应过程中被活化成具有催化活性钼物种的几率更大；而晶相状态的Ａｌ２（ＭｏＯ４）３以及与载体间存在较强相互作用力的钼物种，在甲烷无氧芳构化过程中不起主要催化活性作用．计算得出，甲烷无氧脱氢芳构化反应的表观活化能为８９．８ｋＪ／ｍｏｌ．     

甲烷直接芳构化反应的研究Ⅰ.负载Mo基催化剂在无氧条件下催化性能

研究了催化剂制备方法，Ｍｏ含量，预处理条件和反应条件对无氧条件下ＨＺＳＭ－５负载的Ｍｏ基催化剂上甲烷直接芳构化反应的影响，及积炭和烧炭再生对催化剂性能的影响，发现Ｍｏ含量为３．５～４％时催化剂活性最高，生成苯的速率高达１．２×１０＾－３ｍｏｌ．ｇ＾－１．ｓ＾－１，降低空速和提高反应温度均有利于甲烷的直接芳构化，随着反应的进行，乙烯的选择性不断提高，苯的选择性则不断降低，ＸＰＳ结果表明，反应后催化剂     

水蒸气存在时Mo／HZSM—5催化剂上的甲烷芳构化反应性能

研究了水蒸气存在条件下Ｍｏ／ＨＺＳＭ－５沸石分了筛催化剂上的甲烷芳构化反应行为,发现水蒸气的引入可以明显地降低甲烷芳构化反应的起始温度,从而在较为温和的条件下实现甲烷的活化。适量水蒸气的加入可以在一定程度上改善Ｍｏ／ＨＺＳＭ－５催化剂的稳定性,过量水蒸气的引入则会抑制甲烷芳构化反应,在反应温度为９７３Ｋ时,引入适量的水蒸气对芳构化反应产物的分布没有明显影响。在低温条件下的甲烷芳构化反应过程中检测到     

沸石载体结构对甲烷无氧芳构化性能的影响

考察了担载ＭｏＯ３的沸石催化剂上甲烷的无氧芳构化性能，并与沸石结构相关联。结果表明，孔径与苯分子动态直径相当的ＺＳＭ－５、ＺＳＭ－８、ＺＳＭ－１１和β沸石等是甲烷无氧芳构化催化剂的良好载体，其中３％ＭｏＯ３／ＨＺＳＭ－１１具有最高的甲烷芳构化活性和稳定性，９７３Ｋ下的转化ＨＭＣＭ－４１和ＨＳＡＰＯ－３４为载体时芳构化活化很低，以ＨＭＯＲ、ＨＸ和ＨＹ为载体时仅有少量乙烯生成，而以ＨＳＡＰＯ－５和ＨＳ     

Mo／HZSM—5上甲烷芳构化的诱导期：钼物种的部分还原和碳物种的沉积

在无氧条件下,Ｍｏ／ＨＺＳＭ－５催化剂表现出良好的催化甲烷芳构化性能。采用脉冲反应,ＴＰＳＲ,ＴＰＲ,ＵＶ Ｒａｍａｎ,ＸＲＤ和ＢＥＴ等手段研究了反应的诱导期。ＢＥＴ和ＸＲＤ结果表明,钼物种较好地分散于分子筛的外表面和孔道内。     

Methane Aromatization Under O2-Free Conditions on Zinc Modified Mo/HZSM-5 Catalyst

The influence of Zn content, reaction temperature and pretreatment conditions on a Zn-modified Mo/HZSM-5 catalyst for methane aromatization were studied. It was found that the addition of Zn promoted the reaction. Methane conversion of 10.9% and aromatics selectivity of 96.7% were obtained with a Zn/Mo molar ratio of 0.03 and N₂ pretreatment at 973 K. The results of isopropanol decomposition, NH₃-TPD and TG-DTA suggest that the addition of Zn decrease the acidity of the catalyst, which may be the reason for the high activity on the Mo-Zn/HZSM-5 catalyst. This revised version was published online in June 2006 with corrections to the Cover Date.     

W掺杂对Mo/HZSM-5催化甲烷无氧芳构化性能的影响

采用浸渍法制备了Mo/HZSM-5、Mo-W/HZSM-5和W/HZSM-5三种催化剂。通过XRD、BET、Py-FTIR、H2-TPR、XPS、TEM、NH3-TPD、TPO、TG和Raman等技术对催化剂的物化性质进行表征,并考察其在甲烷无氧芳构化反应中的催化性能。结果表明,相比于Mo/HZSM-5,Mo-W/HZSM-5催化剂表现出更高的CH_4转化率、芳烃收率以及催化稳定性。H_2-TPR和XPS结果表明,Mo-W/HZSM-5中存在更易被还原为W~(4+)的正八面体(WO_6)~(n-)前驱体,反应过程中W4+的形成有助于提高CH_4转化率。同时,积炭表征结果表明,石墨型积炭是导致Mo/HZSM-5催化剂快速失活的主要原因,W掺杂可以抑制MoW/HZSM-5催化剂上石墨型积炭的形成,进而提高催化剂的稳定性。     

Influence of Pretreatment Conditions on Methane Aromatization Performance of Mo／HZSM—5 and Mo—Cu／HZSM—5 Catalysts

Mo/HZSM-5 is a good catalyst for methane aromatization, and the reaction performance of Mo/HZSM-5 and Cu modified Mo/HZSM-5 catalysts under various pretreatment conditions has been studied. The results indicate that the catalyst presented a distinguished catalytic activity, benzene selectivity and a high stability when the bed temperature was raised in N2 atmosphere.     

Methane direct conversion to aromatic hydrocarbons at low reaction temperature

Conversion of pure methane and natural gas with different methane purity to aromatic hydrocarbons at. 773 and 873 K have been investigated. Conversion of methane to aromatics under non-oxidizing conditions can be initiated by higher hydrocarbon mixtures in the feed and, some special coke deposited on Mo/HZSM-5 catalyst at lower reaction temperature. Methane conversion of about 10–20% is obtained at 773 K. The possible reaction mechanism and product phase transformation process for conversion of pure methane and natural gas at lower temperature are proposed. The thermodynamic limitation for methane conversion under non-oxidizing conditions may be circumvented.     

Propane Aromatization over Mo/HZSM-5 Catalysts

Impregnation, mechanical mixing and hydrothermal treatment methods were used to introduce molybdenum species into the HZSM-5 zeolite. The structure and surface acidity of the catalysts were studied by means of XRD, FT-IR, NH3-TPD, TPR and XPS. The effects of Mo content and reaction time on stream on the aromatization of propane were investigated. It was found that the performance of the Mo/HZSM-5 catalyst prepared by the hydrothermal treatment method was much better than that of the other two catalysts. For example, under the reaction conditions of 823 K and 600 h-1, propane conversion and aromatics selectivity over the catalyst prepared by hydrothermal pretreatment could reach 89.17% and 78.56%, respectively. XRD and XPS results showed that the Mo species in the catalysts prepared by hydrothermal treatment were highly dispersed on the surface of the HZSM-5, and larger amounts of them could penetrate into the HZSM-5 channel, as compared with the other two kinds of catalysts. These factors may be responsi     

甲烷在Mo/HZSM-5催化剂上的脱氢聚合反应

对不同Mo含量的Mo／HZSM－5催化剂的结构进行了表征，并对这些催化剂的甲烷非氧气氛下的转化反应进行了考察．催化剂的BET比表面积及酸性随Mo含量的增加而降低，当Mo含量大于5％时，Mo对ZSM－5分子筛的晶型有影响，并出现MoO3物相．甲烷在700℃时可高选择性地生成苯和乙烯，最佳Mo含量大约为2％．纯的MoO3或HZSM－5上该反应几乎不进行，因此，可能是分散的钼氧离子和分子筛的酸中心是甲烷转化的活性中心，只有二者的协同作用才能促进甲烷的转化．反应后催化剂中的钼物种被还原了．催化剂上的积炭可能是催化剂失活的主要原因之一，烧炭后催化剂活性基本恢复．     

Aromatization of methane over different Mo-supported catalysts in the absence of oxygen

Both acidity and structure of the support are important factors in converting methane to aromatics. Lower SiO₂/Al₂O₃ ratio seems to favor the aromatization of methane over the Mo/HZSM-5 catalyst. When Pt is added as a modifier the activity of Mo/HZSM-5 catalyst will decrease slightly, but coke formation will enhanced.     

Propane Aromatization over Mo／HZSM—5 Catalysts

Impregnation,mechanical mixing and hydrothermal treatment methods were used to introduce molybdenum species into the HZSM-5 zeolite ,the structure and surface acidity of the catalysts were studied by means of XRD,FT-IR ,NH3-TPD,TPR and XPS,The effects of Mo content and reaction time on stream on the aromatization of propane were investigated,It was found that the performance of the Mo/HZSM-5 catalst prepared by the hydrothermal treatment method was much better than that of the other two catalysts,For example ,under the reaction conditions of 823 K and 600h^-1, propance conversion and aromatics selectivity over the catalyst prepared by hydrothermal pretreatment could reach 89.17% and 78.56%,respectively,XRD and XPS results showed that the Mo species in the catalysts prepared by hydrothermal treatment were highly dispersed on the surface of the HZSM-5,and lartger amounts of them could penetrate into the HZSM-5 channel ,as compared with the other two kinds of catalysts,These factors may be responsibled for their high activities for propane aromatization,IR and NH3-TPD studies indicated that the number of Broensted acid centers decreased and the Lewis acid centers increased after Mo was introduced into the HZSM-5 zeolite.