高硫合成气制甲硫醇钼硫基催化剂的制备

钼硫基催化剂;含硫化氢合成气;高硫合成气制甲硫醇钼硫基催化剂的制备     

绘画资料中所见的宋代建筑避风与遮阳装修*

甲硫醇(CH_3SH)是医药、农药、饲料和合成材料等领域的重要有机合成中间体,以硫化氢合成气(CO/H_2/H_2S)一步催化合成CH_3SH具有广泛的应用前景.目前,钾改性的二硫化钼材料是一步法合成CH_3SH最高效和广泛的催化剂,但是对催化剂活性相以及K和MoS_2之间物理化学行为认知的不足严重限制了其催化性能.我们主要综述了钾钼基催化剂上3类活性相(MoS_2相、 K-MoS_2相和K_xMoS_2相)在一步法合成CH_3SH过程的研究现状,简要介绍了可控合成3类活性相的关键因素,重点关注了K对MoS_2相的调控作用及其对合成CH_3SH反应机理的影响,并对钾钼基催化剂一步法合成CH_3SH的未来发展进行了展望.     

钾对高硫合成气制甲硫醇磷钼基催化剂的影响

采用等体积共浸渍法,制备了一批不同钾含量的KxMo P/Al2O3(x表示K与Mo摩尔比,0≤x≤3)催化剂,考察其对高硫合成气制甲硫醇性能的影响,并采用X射线衍射分析(XRD)、程序升温还原法(TPR)和激光拉曼光谱(LRS)等技术手段对催化剂进行了表征。结果表明,氧化铝负载的磷钼氧化物前驱体在850℃经H2气还原制备出了Mo P/Al2O3催化剂,少量添加钾催化剂有较高的甲烷选择性,大量添加钾助剂促进了催化剂表面活泼钼硫物种的生成,使得磷化钼基催化剂有较好的甲硫醇选择性,而过量添加钾又会阻碍了甲硫醇的生成。当n(K)/n(Mo)比在2~2.5之间时,磷化钼基催化剂对该反应有较好的催化活性。     

高硫化氢合成气制甲硫醇新型钼基催化剂研究

研究了一系列负载型钼基催化剂催化含高硫化氢合成气制甲硫醇的性能,用XPS和ESR对其进行表征.活性测试显示,钾促进的钼基催化剂催化的反应产物中甲硫醇成为主导产物.几种钼基催化剂合成甲硫醇的活性大小顺序:K₂MoO₄/CoO/SiO₂>K₂MoO₄/SiO₂>MoO₃/K₂CO₃/SiO₂>K₂MoS₄/SiO₂>MoS₂/K₂CO₃/SiO₂.ESR表征显示,反应后的催化剂可以检测到"oxo-Mo(V) "和"thio-Mo(V)"物种.XPS表征显示反应后催化剂中的Mo包含着Mo⁴⁺,Mo⁵⁺和Mo⁶⁺,S包含着S^2-,(S-S)^2-和S⁶⁺三种价态.添加CoO后,"oxo-Mo(V)"含量减少,而"thio-Mo(V)"含量增加,(S-S)^2-物种的生成得到抑制,S^2-物种的量增多.(Mo⁴⁺+Mo⁵⁺)/Mo⁶⁺峰强度比为0.75以及S^2-/(S-S)^2-接近1有利于甲硫醇的生成.本文提出甲硫醇的合成与"Mo-S-K"相关联的反应机理.     

生物基甘油氢解合成1,3-丙二醇催化剂的研究进展

1,3-丙二醇（1,3-PDO）作为聚酯单体原料有广阔的市场空间,在化妆品和医药等领域也被广泛应用.由生物基甘油选择氢解一步法合成1,3-PDO工艺被认为是一条绿色环保和高经济性的技术路线.我们在这里主要介绍了甘油氢解制备1,3-PDO催化剂的研究进展,对催化剂类型、催化剂的合成方法和工艺条件进行了归类总结;分析了多种催化剂体系的甘油氢解反应机理,指出了该反应工业化过程中存在的一些问题,并展望了今后的研究发展方向.     

Cu-Fe基催化剂上合成气直接制取低碳烯烃的研究

我们采用浸渍法制备了γ-Al2O3负载的Cu-Fe基催化剂,并结合其反应性能和XRD、H2-TPR和XPS等表征结果研究了其催化合成气直接制低碳烯烃的反应行为.结果表明,合成气直接制低碳烯烃Cu-Fe基催化剂的活性组分Cu和Fe之间存在明显的协同效应,Cu-Fe基催化剂表现出优异的合成气直接制低碳烯烃反应性能;Cu基催化剂中引入少量Fe组分明显提高了活性组分Cu的分散度,促进了Cu活性组分的还原,进而有利于催化剂反应性能的改进.初步推断Cu-Fe基催化剂上合成气转化生成低碳烯烃的主要反应历程为CO加氢生成含氧化合物(醇醚等)后再脱水生成低碳烯烃.     

浆态床反应器中生物质合成气合成二甲醚的研究

进行了浆态床反应器中,甲醇合成催化剂与分子筛混合制复合催化剂上,生物质制取的合成气(简称生物质合成气)一步法合成二甲醚的研究,重点考察了不同脱水组分和工艺条件对催化剂反应性能的影响,同时,结合NH₃-TPD等手段对催化剂进行了表征。结果表明,含有较弱酸性SAPO-11分子筛的复合催化剂更适合生物质合成气原料气杂质多、氢碳比低的特点,在合成二甲醚反应中具有更高的选择性和稳定性。250℃、5 MPa、500 h^-1时,在甲醇催化剂与SAPO-11分子筛比例为3:1的复合催化剂上,合成气合成二甲醚反应35 h内,CO转化率稳定在40%以上,二甲醚在有机产品中的选择性保持在97%左右。     

抗积炭CH_4/CO_2重整用Ni/Al_2O_3催化剂

甲烷转化制备的合成气是合成液体燃料和含氧有机化合物的原料 .甲烷转化制合成气的方法有甲烷蒸汽重整、甲烷部分氧化和甲烷、二氧化碳重整 3种 [1～ 3] .对于 CH4/CO2 重整反应 ,调节进料比可制备出 H2 /CO≤ 1、富含 CO的合成气 ,它适于羰基合成和 F- T合成 .这种方法一方面充分利用碳资源 ,缓解能源危机 ;一方面可减少温室气体的排放 ,改善人类的居住环境 .目前倍受关注 .CH4/CO2 重整制合成气 ,Rh、Ru、Pd、Ir等贵金属有很高的活性和稳定性 [4] .但其价格昂贵 ,高温易流失 ,商业化困难 .Ni基催化剂的活性与贵金属相当 ,但它易积…     

合成气一步法制备低碳烯烃和液体燃料催化剂研究进展

以合成气作为平台化合物一步法制备低碳烯烃和液体燃料是有效利用碳资源的重要路径,具备流程短、能耗低的特点,有着良好的工业应用前景。合成气一步法直接转化制备低碳烯烃和液体燃料包括两条工艺路线:费托合成路线和双功能催化路线。本综述简述了两种路线的反应机理,重点阐述了费托合成路线中采用添加助剂和惰性载体对铁基和钴基催化剂的优化设计,费托金属粒径、反应条件、催化剂界面结构对催化剂性能和反应过程的影响。详细解析了双功能催化路线中,一氧化碳活化组分和酸性分子筛的选择、金属氧化物粒径与元素比例、分子筛酸度与孔径大小以及一氧化碳活化组分和酸性分子筛的耦合方式对于催化剂性能的影响。总结了两条路线所具备的优势和面临的挑战,并对未来高效催化剂的发展方向进行了展望。     

费托合成钴基催化剂微观结构研究进展

费托合成可将煤、天然气及生物质等各种非石油含碳资源通过合成气转化为各种油品和精细化学品.钴基催化剂因其水煤气变换反应活性低、费托反应活性高、碳链增长能力高的优良特点,在工业应用和相关科学研究上备受关注.钴基催化剂微观活性位的结构和费托反应过程中催化剂的表面吸附物等都会对F-T合成反应的产物分布以及催化性能有影响.本文分...     

Carbon monoxide hydrogenation over molybdenum carbide catalysts

Supported and unsupported molybdenum and molybdenum carbides have been studied as catalysts of CO-H₂ reactions at 570 K and atmospheric pressure. The initial turnover rates of these catalysts were comparable to those of the more active group VIII elements. However, all molybdenum-based catalysts showed a hydrocarbon product distribution different from those for typical group VIII metals. Furthermore, production of a large amount of CO₂ (instead of water) and a high paraffin/olefin ratio reflected high activities of these catalysts for the water-gas shift reaction and hydrogenation, respectively. The high water-gas shift reaction activity allowed a CO-rich synthesis gas to be used efficiently over Mo-based catalysts. The CO-H₂ reactions appear to be structure insensitive on molybdenum carbide catalysts, since the rates were independent of particle size and crystal structure of unsupported catalysts and of metal loading of supported catalysts.     

Production of Mixed Alcohols from Bio-syngas over Mo-based Catalyst

A series of Mo-based catalysts prepared by sol-gel method using citric acid as complexant were successfully applied in the high effcient production of mixed alcohols from bio-syngas, derived from the biomass gasification. The Cu₁Co₁Fe₁Mo₁Zn_0.5-6%K catalyst exhibited a higher activity on the space-time yield of mixed alcohols, compared with the other Mo-based catalysts. The carbon conversion significantly increases with rising temperature below 340 oC, but the alcohol selectivity has an opposite trend. The maximum mixed alcohols yield derived from biomass gasification is 494.8 g/(kg_catal·h) with the C2⁺ (C2-C6 higher alcohols) alcohols of 80.4% under the tested conditions. The alcohol distributions are con-sistent with the Schulz-Flory plots, except methanol. In the alcohols products, the C2⁺ alcohols (higher alcohols) dominate with a weight ratio of 70%-85%. The Mo-based cata-lysts have been characterized by X-ray diffraction and N2 adsorption/desorption. The clean bio-fules of mixed alcohols derived from bio-syngas with higher octane values could be used as transportation fuels or petrol additives.     

Fe（HSO4）3： An efficient,heterogeneous and reusable catalyst for the synthesis of 14-aryl- or alkyl- 14H-dibenzo[a,j]xanthenes

Fe（HSO4）3 has been used as an efficient and recyclable catalyst for the one-pot synthesis of 14-aryl- or alkyl-14Hdibenzo[aj]xanthene derivatives by the reaction of 2-naphtol and aldehydes. Different types of aromatic and aliphatic aldehydes are used in the reaction and in all cases the products were obtained in good to excellent yields.     

Efficient synthesis of xanthenedione derivatives using cesium salt of phosphotungstic acid as a heterogeneous and reusable catalyst in water

Cs_2.5H_0.5PW₁₂O₄₀ has been reported to be an efficient catalyst for the synthesis of 1,8-dioxo-octahydroxanthene from aldehydes and 1,3-cyclohexanedione/dimedone in water. This approach is environmentally benign with clean synthetic procedure, short reaction time, easy workup procedure, excellent yield, and regeneration of catalyst, which made this protocol efficient and safe.     

Brønsted acidic ionic liquid [HMIm]BF4 promoted simple and efficient one-pot green synthesis of isoxazolyl-1,3-benzoxazines at ambient temperature

Abstract

Brønsted acidic ionic liquid [HMIm]BF₄ has been used as a nonvolatile, ecofriendly solvent, and catalytic medium for the one-pot green synthesis of isoxazolyl-1,3-benzoxazines. The reaction afforded excellent yield in short reaction time, and avoids multistep synthesis. The easy of recyclability of the IL makes the reaction economically and potentially viable for commercial applications.     

Synthesis of one-pot pyrazolo[4′,3′:5,6]pyrano[2,3-c]phenazin-15-yl) methanone derivatives via a multi-component using Fe3O4@TiO2-SO3H as a recoverable magnetic catalyst under microwave irradiation

ABSTRACT

A new one-pot method for the synthesis four-component of pyrazolo[4′,3′:5,6]pyrano[2,3-c]phenazin-15-yl)methanone derivatives has been developed in the presence of nano Fe₃O₄@TiO₂-SO₃H catalysts (heterogeneous acid) under microwave conditions and in a solvent-free environment at 180?W. One of the benefits of using this catalyst was its re-use in subsequent stages of its reaction without much loss in its activity, which was carried out by an external magnet and recovered. The catalyst was synthesized and characterized by XRD, EDX, TEM, FESEM, TGA-DTA, BET, VSM and AFM. The productivity of the products obtained from this protocol (MAOS) is significantly high and the shorter reaction time in the synthesis process over the reflux method. These results showed advantages for synthesis, such as mild reaction conditions, no use of toxic catalysts in the laboratory, solvent-free environment, low energy consumption and Economically Affordable.     

A recyclable and highly effective sulfated TiO2-P25 for the synthesis of quinoxaline and dipyridophenazine derivatives at room temperature

Sulfated TiO₂-P25 has been prepared using H₂SO₄ and used for the synthesis of quinoxaline and dipyridophenazine derivatives. Sulfate loading by H₂SO₄ increases the Lewis acidity of TiO₂-P25. This catalyst gives excellent yield with less reaction time and it is an inexpensive, easily recyclable catalyst for this reaction.     

R&D activities in Japan on methanol synthesis from CO2 and H2

Methanol synthesis from CO₂ and H₂ can be a useful process for conversion and transportation of hydrogen energy derived from non-fossil energies. More than ten research groups in Japan have extensively investigated the methanol synthesis from both academic and practical points of view. Recent R&D activities in Japan for developing high performance catalysts, for elucidating the reaction mechanism and also for operating a bench scale plant have been reviewed in this paper.     

Base-promoted reaction of C60Cl6 with thioamides: an access to [60]fullereno[1,9-d] thiazoles

Regioselective reaction of C₆₀Cl₆ with thioamides via a radical annulation to form fullereno thiazole derivatives is reported. The reaction is promoted by K₂CO₃, which might deprotonate thioamide to initiate a single electron transfer from thioamide anion to C₆₀Cl₆. The experiments with various thioamides establish the proposed base-promoted reaction as a facile route for synthesis of fullereno fused thiazole derivatives starting from C₆₀Cl₆, a prevalent synthon in fullerene chemistry. In addition, the tunable electrochemical properties of the fullereno thiazole products have been investigated for their potential photovoltaic application.     

Electrochemical catalysis and corrosion of defective MoS2: Microscopic behaviors and density-functional-theory calculations

MoS₂ is an intriguing layered material widely used in catalysis, lubrication, optoelectronic devices and many other fields, where various structural defects (e.g., vacancies, edges, dopants) will be created in the synthesis and application processes. The promoting effect of defects on the electrochemical reactions, for example, oxygen reduction reaction (ORR) and hydrogen evolution reaction (HER), on MoS₂ has been intensively pursued for efficient catalysts, but should be avoided for durable and superior lubricants and optoelectronic devices working in many atmospheric/aqueous environments. Here, from the perspectives of density-functional-theory simulation, we review the contemporary research progresses on these electrochemical reactions and the underlying microscopic mechanisms of defective MoS₂, and finally project the future research trends and challenges on the electrochemical catalysis and corrosion of defective MoS₂.