甲烷氧化偶联锂/氧化镁催化剂和纳米催化剂

The Li/MgO catalyst and nanocatalyst were prepared by the incipient wetness impregnation and sol-gel method, respectively. The catalytic performance of the Li/MgO catalyst and nanocatalyst on oxidative coupling of methane was compared. The catalysts prepared in two ways were characterized by X-ray powder diffraction, Brunauer-Emmett-Teller surface and transmission electron microscope. The catalyst was tested at temperature of 973-1073 K with constant total pressure of 101 kPa. Experimental results showed that Li/MgO nanocatalyst in the oxidative coupling of methane would result in higher conversion of methane, higher selectivity, and higher yield of main products (ethane and ethylene) compared to ordinary catalyst. The results show the improved influence of nanoscale Li/MgO catalyst performance on oxidative coupling of methane.     

Effect of quenching on the methane coupling reaction

The effect of reaction mixture quenching on C₂ product formation in the methane coupling reaction on La₂O₃/CaO is disclosed. For reaction with the mixture (vol. %): 54.5 CH₄, 9.1 O₂ and 36.4 N₂ at 973 K, quenching of products results in a two-fold decrease in C₂ product yield. The results give evidence that in methane oxidative coupling methyl radical formation can occur in the gas phase to an extent comparable with that on the catalyst surface. The effect described must be taken into account in the case of an industrial application of methane oxidative coupling, too, because quenching is a regular procedure in the high temperature oxidative processes.     

甲烷氧化偶联Na2WO4-Mn/SiO2催化剂热效应的研究

采用固定床微型反应装置,研究了甲烷氧化偶联反应过程中Na2WO4-Mn/S iO2催化剂床层的热效应和催化性能的关系,考察了反应炉温、CH4/O2比和反应气体空速对催化剂床层热点分布的影响.研究结果表明,甲烷氧化偶联催化剂床层的热效应强烈依赖于反应条件.反应炉温越高,CH4/O2比越低,反应气体空速越大,催化剂床层的热点温度越高.结合催化性能和热效应关系的研究,为优化甲烷氧化偶联的反应操作提供了实验依据.     

甲烷氧化偶联制烯烃的热力学平衡限度

选择适宜的热力学模型对甲烷氧化偶联制烯烃体系的热力学平衡进行分析，考察温度﹑压力﹑进料组成对体系组分的平衡限度影响。研究发现，在甲烷氧化偶联制烯烃体系中，H2、CO的生成相对容易，C2产物（C2H4、C2H6）不容易生成。通过计算，得到了该体系有利于烯烃生成的反应条件，500℃～800℃、1.5MPa、烷氧摩尔比为7。实验为甲烷氧化偶联反应器和催化剂的开发研究提供热力学依据。     

甲烷氧化偶联Mn_2O_3-Na_2WO_4/SiO_2催化剂——Ⅲ.高温(700—800℃)XRD和XPS研究

在本工作的研究报导Ⅰ和Ⅱ(见本期477页和481页)中,已对Mn_2O_3-Na_2WO_4/SiO_2催化剂活性相的表面分散状态、表面氧种和表面结构进行了详细表征。但甲烷氧化偶联反应在高温(700—800℃)下进行。本文进一步对该催化剂在此反应高温下的XRD和XPS研究表明,其表面状态较室温下有显著变化,结合前文的室温下表征结果,使我们对高温反应条件下该催化剂组分间协同作用、表面活性氧种和活性位结构性质有了进一步的理解,并有可能对其甲烷催化活化机理进行较为深入的探讨。     

THE ROLE OF LATTICE AND GASEOUS OXYGEN ON THE OXIDATIVE COUPLING OF METHANE STUDIED BY A PULSE REACTION TECHNIQUE

A comparative study of the role of lattice and gaseous oxygen in theoxidative coupling of methane over Na~ /Cao and Ca_xSr_(1-x)TiO_3 perovskiteoxide catalysts was performed by using a pulse reaction technique with CH_4,O_2 and mixtures of CH_4and O_2.It was found that there is an oxygen species onthe Surface of Cao which is active only for the total oxidation of methane at thereaction temperature.These oxygen species.once reacted with methane andconsumed,can be regenerated by the adsorption of oxygen molecules from thegas phase or by the migration of the lattice oxysen from the bulk onto thesurface.In contrast,no such oxygen species and no reaction can be detected bymethane pulsed over Ca_xSr_(1-x)TiO_3perovskite oxide catalysts.Na~ can heavilysuppress the non-selective oxygen species on the surface,and When 5mol%Na~ was incorporated onto the surface of Cao,the sample showed no reactivityto methane.When oxygen exists in the gas phase,or the pulse containsmethane and oxygen,the reaction over(Cao is mai     

镍基中空纤维催化剂实现甲烷高效电催化转化

随着天然气以及页岩气为代表的非常规天然气的大规模开采,甲烷作为化工原料的直接转化利用受到了越来越多的关注.然而,甲烷分子具有极其稳定的正四面体结构,其物理化学性质非常稳定,如具有高达439 kJ/mol的C-H键能、极弱的电子亲和力、相当大的离子化能量和低的极化率,这都使得甲烷分子C-H键的活化相当困难.如何实现甲烷直接高效催化转化被誉为催化领域的'皇冠式'课题.与经甲烷重整制合成气,然后通过F-T合成获取化学品的间接转化法相比,甲烷直接转化无论在物料、能量转换效率还是在设备成本、环境保护等方面都有着非常明显的优势.以甲烷氧化偶联以及非氧化偶联(如无氧芳构化等)为典型代表的甲烷直接转化研究不断取得突破,但其各自都存在一定的局限性.相比于热催化转化路径,电催化转化路径在许多方面存在着十分明显的优势:(1)反应条件温和,甚至在常温常压条件下也能实现甲烷电催化转化反应的发生;(2)可调控程度高,仅需调节关键实验参数如电压和电流等,就能实现对反应过程热力学以及动力学的调控;(3)能够利用可再生电能驱动甲烷转化反应的发生,可将低品阶的电能转化并存储为化学能.本文采用Ni中空纤维作为基底,在其表面构筑NiO活性层,将NiO@Ni中空纤维作为电极,实现了常温常压条件下的甲烷电催化转化.通过X射线衍射、扫描电镜、透射电镜等表征手段,确定了中空纤维特有的多孔三维结构、气体传输规律、NiO活性层分布状态等物化性质.通过电化学交流阻抗与循环伏安等测试手段,获得了电荷传递、电化学活性比表面积等电化学性质.恒电压电氧化甲烷研究发现,1%NiO@Ni中空纤维具有最优的催化活性,分别在1.44 V与1.46 V(vs.RHE)电势下获得54%的甲醇法拉第效率和85%的乙醇法拉第效率.     

Modeling the oxidative coupling of methane： Heterogeneous chemistry coupled with 3D flow field simulation

The oxidative coupling of methane (OCM) over titanate perovskite catalyst has been developed by three-dimensional numerical simulations of flow field coupled with heat transfer as well as heterogeneous kinetic model. The reaction was assumed to take place both in the gas phase and on the catalytic surface. Kinetic rate constants were experimentally obtained using a ten step kinetic model. The simulation results agree quite well with the data of OCM experiments, which were used to investigate the effect of temperature on the selectivity and conversion obtained in the methane oxidative coupling process. The conversion of methane linearly increased with temperature and the selectivity of C2 was practically constant in the temperature range of 973–1073 K. The study shows that CFD tools make it possible to implement the heterogeneous kinetic model even for high exothermic reaction such as OCM.     

Interaction of Methane and Oxygen with the Surface of Manganese Oxide-Containing Catalysts

We used pulsed reduction and temperature programmed oxidation to study the interaction of methane and oxygen with the surface of manganese oxide-containing catalysts. We hypothesized that during oxidative dimerization of methane, the phase supplying strongly bound oxygen for selective methane coupling is an acceptor for weakly bound oxygen of the phase catalyzing exhaustive oxidation.     

STUDY OF THE CATALYTIC TECHNOLOGY IN THE OXIDATIVE COUPLING OF METHANE

The temperature of the catalyst bed in the oxidative coupling ofmethane would rise and be higher than the wall temperature when the amountof catalyst, the space velocity and the ratio of oxygen to methane wereincreased. Various aspects of the catalytic technology including the thickness ofthe catalyst bed, the mode of catalyst charge, the ratio of CH_4 to O_2 and thespece velocity were studied. An optimum temperature of the catalyst bed forhigher methane conversion and C_2 selectivity was investigated. It was foundthat the burning of methane in the gas phase to form CO occurred at certaintemperatures with some ratios of oxygen to methane. Additionally, the effectof adding water to the reaction feed gas was studied.     

Non-oxidative dehydro-oligomerization of methane to higher molecular weight hydrocarbons at low temperatures

The non-oxidative dehydro-oligomerization of methane to higher molecular weight hydrocarbons such as aroma tics and C2 hydrocarbons in a low temperature range of 773-973 K with Mo/HZSM-5,Mo-Zr/HZSM-5 and Mo-W/HZSM-5 catalysts is studied.The means for enhancing the activity and stability of the Mo-containing catalysts under the reaction conditions is reported.Quite a stable methane conversion rate of over 10% with a high selectivity to the higher hydrocarbons has been obtained at a temperature of 973 K.Pure methane conversions of about 5.2% and 2.0% have been obtained at 923 and 873 K,respectively.In addition,accompanied by the C2-C3 mixture,tht- methane reaction can be initiated even at a lower temperature and the conversion rate of methane is enhanced by the presence of tne initiator of C2-C3 hydrocarbons.Compared with methane oxidative coupling to ethylene,the novel way for methane transformation is significant and reasonable for its lower reaction temperatures and high selectivity to the desired prod     

甲烷在SrO－La_2O_3／CaO催化剂上的氧化偶联──IV．热点温度效应和反应气中添加CO_2的影响

研究了甲烷在ＬＣ和ＳＬＣ催化剂体系上氧化偶联反应过程的热效应现象和反应气中添加ＣＯ２对催化剂反应行为的影响．在不使用稀释气的情况下，当反应温度由８７３升至９２３Ｋ时，反应活性存在一个突变点．这主要是由ＣＨ４燃烧反应放出大量热使催化剂床层的局部温度很高，形成一个局部过热区，因此引发甲烷氧化偶联．此即所谓热点温度效应，它严重影响催化剂活性评价结果的可靠性和重复性．在反应气中添加ＣＯ２对ＬＣ几乎无影响；由于ＳＬＣ中各组分与ＣＯ２作用生成碳酸盐，使催化剂表面氧浓度显著减少，导致催化剂的反应活性大大降低和严重失活．     

STUDY ON THE OXIDATIVE COUPLING OF METHANE III.CATALYTIC PERFORMANCE OF TiO2-BASED CATALYSTS STUDIED BY CO2-TPD AND TPR-TPO

The effects of surface acidity-basicity and surface oxidation reduction property of Li-La-Mn/TiO2 (I) and Li-La-Mn-W/TiO2 (II) catalysts on oxidative coupling of methane were studied by CO2-temperature programmed desorption (CO2-TPD) and temperature programmed reduction temperature programmed oxidation (TPR-TPO). The results show that there exist strong basic sites on catalysts I and II, but the quantity of these sites on catalyst II is more than that on catalyst I. Besides, the strength of basics site on catalyst II is stronger than that on catalyst I. The surface of catalyst II is easier to reduce and re-oxidize than that of catalyst I. The surface of catalyst II is easier to reduce and re-oxidize than of catalyst I, and the extent of reduction and reoxidation of catalyst II is more intensive than catalyst I, which results in a lowing of the reaction temperature and enhances the activity and C2 hydrocarbon yield as well as gas hourly space velocity(GHSV). Catalyst II is excellent for the oxidative coupling of methane (OCM).     

Formation of Acetylene in the Reaction of Methane with Iron Carbide Cluster Anions FeC3− under High‐Temperature Conditions

The underlying mechanism for non‐oxidative methane aromatization remains controversial owing to the lack of experimental evidence for the formation of the first C?C bond. For the first time, the elementary reaction of methane with atomic clusters (FeC₃^?) under high‐temperature conditions to produce C?C coupling products has been characterized by mass spectrometry. With the elevation of temperature from 300 K to 610 K, the production of acetylene, the important intermediate proposed in a monofunctional mechanism of methane aromatization, was significantly enhanced, which can be well‐rationalized by quantum chemistry calculations. This study narrows the gap between gas‐phase and condensed‐phase studies on methane conversion and suggests that the monofunctional mechanism probably operates in non‐oxidative methane aromatization.     

锂/铌镁催化剂中碳酸锂的熔点与甲烷氧化偶联反应的活化和失活的关系

研究了铌掺杂的Li/MgO甲烷氧化偶联催化剂的反应性质及铌的助剂作用。铌的引入使得该催化剂上甲烷氧化偶联反应的活化温度降低50℃以上, 使此温度降到了催化剂中碳酸锂的熔点附近。试验观察到部分催化剂上甲烷氧化偶联反应的活性曲线在碳酸锂的熔点附近有一转折, 这一转折现象的出现与否及程度取决于制备条件。在碳酸锂的熔点附近, 含有铌的催化剂得到活化, 观察到无稀释气体时的反应引燃现象, 即温度增加几度活性便达到最大值。当在比碳酸锂熔点稍高的温度下且不稀释时反应, 含铌催化剂活性很高但很快失活, 在稍低于此熔点下则不失活, 但活性较低。这些试验结果表明, 含铌催化剂的活化与失活均与催化剂中的碳酸锂的相变化有关。试验还观察到了在稍高于碳酸锂的熔点下做寿命试验时, 甲烷氧化偶联反应的振荡现象。     

表面偶联甲基自由基实现低温高效甲烷氧化偶联

天然气作为一种低碳清洁能源,其储量大,价格低,被认为是最有前途的石油替代资源之一.而以天然气的主要成分——甲烷为原料来生产高价值化学品被认为是石化工业中实现天然气取代石油为原料新化工路线的技术基础,具有极为可观的社会经济价值.目前甲烷的化学利用主要采用间接转化法,即先从甲烷制合成气,再由合成气制备各种化工原料和油品.但...     

STUDIES OF MULTICOMPONENT COMPLEX OXIDE CATALYSTS FOR OXIDATIVE COUPLING OF METHANE VII.EFFECT OF CALCINATION TEMPERATURE ON Ti-La-Li PEROVSKITE-TYPE OXIDE CATALYSTS

The correlations of the calcination temperature.structure and catalvtic activity of the LiLa_（0.5）Ti_（0.5）O_(2-(?)) catalvsts with main phase and major active phase of perovskite-type trmary complex oxide LaTi_(l-y)Li_yO_(3-λ）m the Oxidative coupling of methane(OCM)have been studied The surface and bulk structures of the catalysts were characterized by means of XRD,XPS. IR.BFT and so on. The results clearly indicated that the effect of calcination temperature on the activity for the oxidative coupling of methaneis twofold On one hand.high calcination temperature is favoragble for Lisubstitution for Ti~(3 )into the lattice of LaTiO_3 and the production of moreoxygen vacancies at which active oxygen species are formed However,excessivelv high calcmation temperature makes Li~ substitution for Ti~(3 )less due to a httle change of structure or phases of the catalvst On the otherhand,the conversion of CH_4 drops because of the decrease of surface area,when the calcination temperature is raised.     

K＋－SrO－La_2O_3／ZnO催化剂上甲烷氧化偶联反应Ⅰ．催化活性和反应气中添加CO_2的影响

Ｋ＋┐ＳｒＯ┐Ｌａ２Ｏ３／ＺｎＯ催化剂上甲烷氧化偶联反应＊Ⅰ．催化活性和反应气中添加ＣＯ２的影响余林徐奕德＊＊郭燮贤（中国科学院大连化学物理研究所催化基础国家重点实验室，大连１１６０２３）关键词钾离子，氧化锶，氧化镧，氧化锌，金属氧化物催化剂，甲烷，...     

Conversion of natural gas to C_2 hydrocarbons via cold plasma technology

The plasma technology served as a tool in unconventional catalysis has been used in natural gas conversion,because the traditional catalytic methane oxidative coupling reaction must be performed at high temperature on account of the stability of methane molecule.The focus of this research is to develop a process of converting methane to C2 hydrocarbons with non-equilibrium plasma technology at room temperature and atmospheric pressure.It was found that methane conversion increased and the selectivity of C2 hydrocarbons decreased with the voltage.The optimum input voltage range was 40-80 V corresponding to high yield of C2 hydrocarbons.Methane conversion decreased and the selectivity of C2 hydrocarbons increased with the inlet flow rate of methane.The proper methane flow rate was 20-40 ml/min (corresponding residence time 10-20 s).The experimental results show that methane conversion was 47% and the selectivity of C2 hydrocarbons was 40% under the proper condition using atmospheric DBD cold plasma technology.It was found that the breakdown voltage of methane VB was determined by the type of electrode and the discharge gap width in this glow discharge reactor.The breakdown voltage of methane VB,min derived from the Paschen law equation was established.     

Conversion of natural gas to C2 hydrocarbons via cold plasma technology

The plasma technology served as a tool in unconventional catalysis has been used in natural gas conversion, because the traditional catalytic methane oxidative coupling reaction must be performed at high temperature on account of the stability of methane molecule. The focus of this research is to develop a process of converting methane to C2 hydrocarbons with non-equilibrium plasma technology at room temperature and atmospheric pressure. It was found that methane conversion increased and the selectivity of C2 hydrocarbons decreased with the voltage. The optimum input voltage range was 40-80 V corresponding to high yield of C2 hydrocarbons. Methane conversion decreased and the selectivity of C2 hydrocarbons increased with the inlet flow rate of methane. The proper methane flow rate was 20-40 ml/min (corresponding residence time 10-20 s). The experimental results show that methane conversion was 47% and the selectivity of C2 hydrocarbons was 40% under the proper condition using atmospheric DBD cold plasma technology. It was found that the breakdown voltage of methane VB was determined by the type of electrode and the discharge gap width in this glow discharge reactor. The breakdown voltage of methane VB,min derived from the Paschen law equation was established.