碱金属氟化物/La2O3催化剂上的甲烷氧化偶联

研究了碱金属氟化物添加剂对Ｌａ２Ｏ３的甲烷氧化偶联反应催化性能的影响，发现ＮａＦ的促进效应最明显，还研究了ＮａＦ含量对催化剂 批表面积、活性选择性的影响，发现催人上比表面积与活性存在着对应关系，温度改变，催化剂的活性选择性了将随之发生变化，在１０７３Ｋ，Ｃ２收率达到最大值，约１８．０％，应用ＸＲＤ，ＸＰＳ等技术对反应前后催化剂的表面组成和结构进行了表征。     

Ni-Cu-Al2O3催化剂的活性相及作用机理

对新鲜和７００℃反应过的Ｎｉ－Ａｌ和Ｎｉ－Ｃｕ－Ａｌ催化剂的ＸＲＤ、ＸＰＳ表征结果表明，新鲜ＮｉＯ－Ａｌ２Ｏ３催化剂体相中的ＮｉＯ，ＮｉＡｌ２Ｏ４经７００℃反应后转变成金属Ｎｉ，同时表面的镍物种由单一的ＮｉＡｌ２Ｏ４变为ＮｉＡｌ２Ｏ４，ＮｉＯ和金属Ｎｉ的混合物，经反应后ＮｉＯ－ＣｕＯ－Ａｌ２Ｏ３催化剂体相和表相中的ＮｉＡｌ２Ｏ４，ＣｕＡｌ２Ｏ４均转变成为Ｎｉ－Ｃｕ合金，这是此催化剂对甲烷部分氧化反     

Ni/MWCNT及镧改性Ni/MWCNT催化CO2甲烷化反应的性能

以多壁碳纳米管(MWCNT)为载体, 通过浸渍法制备了负载型镍催化剂和稀土镧改性的镍催化剂, 并对其二氧化碳甲烷化的催化性能进行了研究. 借助比表面积测试、程序升温还原(TPR)、X射线衍射(XRD)和X射线光电子能谱(XPS)等表征手段研究了稀土镧的添加对Ni/MWCNT催化剂结构和表面组成、催化剂还原性能以及CO₂甲烷化反应性能的影响. 结果表明: 稀土镧改性的Ni/MWCNT较Ni/MWCNT催化剂具有更好的CO₂甲烷化活性, 镧组分的加入提高了催化剂表面的镍物种浓度和分散度, 弱化了氧化镍与载体MWCNT之间的相互作用, 促进了氧化镍的还原, 同时提高了表面镍物种的电子密度, 增加了对反应物的吸附能力, 从而提高了其CO₂甲烷化活性. 制备过程中稀土镧的添加次序对催化性能有较明显的影响, 其活性顺序为先浸渍镧后浸渍镍制备的催化剂活性明显好于先浸渍镍后浸渍镧制备的催化剂.     

助剂铬对Ni/MgO催化剂CVD法制备碳纳米管的促进作用

采用溶胶-凝胶法制备了助剂Cr改性的Ni/MgO催化剂, 用化学气相沉积(CVD)法在600 ℃下裂解甲烷生长碳纳米管, 研究了助剂Cr的引入对催化剂微结构和制备碳纳米管性能的影响. 催化剂样品用XRD, TPR和CO-TPD进行了分析, 制备的碳纳米管用TEM和XRD进行了表征. 实验结果表明, NiO和MgO之间存在着强相互作用而形成固溶体, Ni/MgO催化剂经氢气处理后其中的镍氧化物只有极少部分被还原成为镍. 助剂铬的引入明显促进了镍的还原, 使得催化剂表面的Ni活性中心数增多, 从而使催化剂的活性和性能得到了明显的改进. 在加入助剂后碳纳米管的产率明显增加, 当Cr质量分数为8%时, 碳纳米管的产量为未加助剂时产量的5倍, 碳纳米管和催化剂的质量比达到1928. 当Cr含量进一步增加时, Ni在催剂表面聚集形成大颗粒, 制备出的产品中含有大量的碳纳米纤维和无定形碳. 以8%Cr-Ni/MgO催化剂合成的碳纳米管具有比较高的产率且质量较好.     

MOR负载的自还原型双功能催化剂用于催化纤维素氢解制乙二醇的研究

以丝光沸石分子筛(MOR)为载体,以高温生物碳源分解产物H2或CO为还原剂,采用等体积浸渍法制备自还原型双功能催化剂Ni-W/MOR,不经过还原过程直接将其应用于纤维素水相氢解制备低碳乙二醇的研究。考察了催化剂的煅烧温度、活性金属含量配比对纤维素转化率和目标产物收率的影响。结果表明,催化剂的煅烧温度在773 K为宜;XRD表征结果说明,催化剂中活性金属结晶度和晶体的种类与催化剂的配比有关;TEM照片可直观地说明,采用上述方法制备的催化剂中活性金属在载体上具有较好的分散性,粒径均小于20 nm。当Ni、W含量分别为10%和15%,煅烧温度为773 K,反应条件为513 K、5.0 M Pa、2 h时低碳多元醇总收率为56.92%,其中,乙二醇收率为52.30%。     

COx-Free Hydrogen and Carbon Nanofibers Produced from Direct Decomposition of Methane on Nickel-Based Catalysts

Direct decomposition of methane was carried out using a fixed-bed reactor at 700℃for the production of COx-free hydrogen and carbon nanofibers. The catalytic performance of NiO-M/SiO2 catalysts (where M=AgO, CoO, CuO, FeO, MnOx and MoO) in methane decomposition was investigated. The experimental results indicate that among the tested catalysts, NiO/SiO2 promoted with CuO give the highest hydrogen yield. In addition, the examination of the most suitable catalyst support, including Al2O3, CeO2, La2O3, SiO2, and TiO2, shows that the decomposition of methane over NiO-CuO favors SiO2 support. Furthermore, the optimum ratio of NiO to CuO on SiO2 support for methane decomposition was determined. The experimental results show that the optimum weight ratio of NiO to CuO fell at 8:2 (w/w) since the highest yield of hydrogen was obtained over this catalyst.     

催化裂解CH4制备碳纳米管的影响因素

以柠檬酸法制备的Fe-MgO、Co-MgO和Ni-MgO为催化剂,CH4为碳源气,H2为还原气,在873、973和1073 K制备出碳纳米管,通过TEM和拉曼光谱表征,讨论了催化剂、制备温度、反应时间等因素对碳纳米管形貌、产率和内部结构的影响.结果表明:不同的催化剂在相同的温度下制备的碳纳米管的形态和内部结构有很大的差异.其中Fe-MgO催化剂制备的碳纳米管管径粗,且大小不均匀,而Ni-MgO催化剂制备的碳纳米管管径较细、较均匀.碳纳米管的产率随着裂解温度的变化而改变.Fe-MgO催化剂制备碳纳米管的产率随制备温度的升高而提高,而Ni-MgO催化剂制备碳纳米管的产率随制备温度的升高而降低.Fe-MgO催化剂制备碳纳米管,在1073K甚至更高的制备温度才能达到其最高产率.Co-MgO催化剂制备碳纳米管的产率在973 K左右产率较高,而用Ni-MgO催化剂制备碳纳米管,则在873 K甚至更低的制备温度就能达到最高产率.反应时间与碳纳米管的产率不成正比,有一最佳反应时间,如Ni-MgO催化剂的最佳反应时间为2 h.     

La2O3 和CeO2对CH4-CO2重整Ni/MgO催化剂结构和性能的影响

采用共沉淀方法制备了NiO-MgO、NiO-La2O3-MgO、NiO-CeO2-MgO三种催化剂，用BET、XRD、TPR、XPS、TG及活性评价等方法考察了La2O3、CeO2助剂对NiO-MgO物化性质和CH4-CO2重整反应性能的影响.实验结果表明，三种催化剂中镍物种以镍镁固溶体形式存在.与NiO-MgO相比， NiO-La2O3-MgO、NiO-CeO2-MgO具有较高比表面积，且其镍物种可还原能力有所增强， NiO-CeO2-MgO尤为明显. La2O3、CeO2均在一定程度上改善了NiO-MgO的CH4-CO2重整反应性能，提高了镍晶粒的抗烧结能力.但二者的作用机制有所差异， La2O3和CeO2分别主要作为结构助剂和电子助剂发挥作用.     

担载镍催化剂上乙炔与甲酸甲酯加氢酯化合成丙烯酸甲酯:担载量和焙烧温度的影响(英文)

以ＮｉＯ担载量为０．０８ｗｔ％～１８．７ｗｔ％及焙烧温度为６２３ Ｋ～８７３ Ｋ的ＮｉＯ／Ａｌ２Ｏ３催化剂进行乙炔与甲酸甲酯的加氢酯化反应,并结合ＴＰＲ、ＸＰＳ、ＸＲＤ和ＢＥＴ技术对催化剂进行表征。催化剂在制备过程中,镍离子与载体氧化铝间的相互作用产生两种不同的镍物种,ＮｉＯ晶相和ＮｉＡｌ２Ｏ４类物种,它们间的比例随担载量及焙烧温度而异,因而表现出其对乙炔与甲酸甲酯加氢酯化不同的反应性能。实验结果表明,在７７３ Ｋ焙烧的１０Ｗｔ％ＮｉＯ／Ａｌ_２Ｏ_３最适合乙炔与甲酸甲酯的加氢酯化反应。     

预还原催化剂LaNiO3, La4Ni3O10, La3Ni2O7和La2NiO4 催化分解CH4制碳纳米管 的研究

通过预还原的LaNiO3,La4Ni3O10,La3Ni2O7和La2NiO4催化分解CH4可以制备大量高度石墨化的碳纳米管。还原前后的催化剂的结构和组分通过X射线衍射(XRD)测定。所制得的碳纳米管由扫描电镜(TEM)、X射线光电子能谱(XPS)表征。碳纳米管在空气在的热氧化性由热重实验(TG)测定。实验结果表明不同催化剂前驱中的La/Ni比会影响碳纳米管的管径分布和石墨化程度。La/Ni比越小,碳纳米管的管径越大,石墨化程度越高。     

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 C<Subscript>2</Subscript>-C<Subscript>4</Subscript> alcohols over copper-containing catalysts on carbon and fluorocarbon fibers

Carbon and fluorocarbon fibers were used as carriers for the preparation of copper catalysts from copper oxalate as precursor. The catalytic properties of catalyst were studied in the reaction of the dehydrogenation of C₂-C₄ alcohols by the pulsed microcatalytic method. The effect of the copper content in the catalyst, the reaction temperature on the degree of conversion, and the relation of the reaction channels were studied. The electron microphotographs were obtained, specific surfaces were measured, and X-ray pictures and infrared spectra of catalysts were taken. The activity of the catalysts on the carbon and fluorocarbon fibers in the dehydration-dehydrogenation reactions of C₂-C₄ alcohols was comparatively estimated. It was shown that the selectivity of the products from the dehydrogenation reaction is higher for the Cu-fluorocarbon fiber catalyst.     

碱性助剂的添加对Ni/CaO-Al2O3催化剂性能的影响

在CH4、 CO2和O2制合成气的反应中, 通过在Ni/CaO-Al2O3催化剂中添加碱性助剂K2O、 MgO和La2O3, 使催化剂的性能得到了改善. 实验结果表明, MgO和La2O3助剂的添加, 有利于提高催化剂的活性;添加K2O, 却相反. 测得催化剂上积炭量的顺序为: Ni-La2O3/CaO-Al2O3相似文献   

流化床甲烷部分氧化制合成气Ni催化剂及助剂La的作用

在流化床中,考察了不同Ni担载量的Ni/γ-Al2O3催化剂对POM反应的催化性能,以8％Ni最佳,TPR结果表明。催化剂表面主要有两种化学状态的NiO。当镍担载量≤2％时,催化剂表面 仅存在一种高温下才能被还原的NiO,在Ni催化剂中添加La,可削弱NiO与载体间的相互作用,并且可减缓在CH4＋O2气氛下升温过程中NiO与载体发生强相互作用 生成NiAl2O4,因此添加La的Ni催化剂在750℃就能引发甲烷部分氧化（POM）反应,且反应引发后可获得与经700℃H2还原后的Ni^0催化剂相同的反应性能。     

甲烷与二氧化碳重整制取合成气反应的研究 (I)Sr_(1-x)La_xNiAl_(11)O_(19)催化活性表征

对具有磁铅石结构的Ｓｒ１－ｘＬａｘＮｉＡｌ１１Ｏ１９对甲烷与二氧化碳重整反应的催化活性、积炭量和稳定性进行了研究．不同还原温度下催化剂的ＸＲＤ和催化活性的实验结果表明，金属镍是ＣＨ４＋ＣＯ２重整反应的活性组分，金属镍含量越大，反应活性越高．反应后催化剂积炭量的分析结果说明，在相同镍含量和分散度的情况下，Ｌａ３＋离子对Ｓｒ２＋离子调变，可以降低催化剂的表面酸性，提高催化剂的抗积炭能力．ＬａＮｉＡｌ１１Ｏ１９是一种具有较好催化活性、稳定性和抗积炭性能的催化剂．     

REDUCTION OF NO BY CO OVER NiWO4, NiO, AND WO3 CATALYSTS

We present a comparative study of NiWO₄, NiO, and WO₃ catalysts for simultaneous conversion of NO and CO. Samples were synthesized by reacting ammonium metatungstate and/or nickel nitrate at high temperature (773 K to 903 K) under an oxygen stream. Catalysts were characterized by X-ray diffraction, surface area measurements, energy dispersive spectroscopy and scanning electron microscopy. The catalytic reduction of NO by CO took place in the temperature range (523 to 973) K under highly reductive conditions (NO:CO= 1:5) over NiWO₄NiO, and WO₃, respectively. The 100 % NO conversion at GHSV of 11460 h^-1 was achieved at 773 K over NiWO₄ and at 848 K over NiO. The WO₃ was deactivated at 898 K. However, in the range (523 to 723) K NiO was more active than NiWO₄ and WO₃ catalysts.     

Ni/Al2O3 catalysts for syngas methanation: Effect of Mn promoter

Ni/Al2O3 catalysts with different amounts of manganese ranging from 1 to 3 wt% as promoter were prepared by co-impregnation method. The catalysts were characterized by N2 physisorption, XRD, TPR, SEM and TEM. Their catalytic activity towards syngas methanation reaction was also investigated using a fixed-bed integral reactor. It was demonstrated that the addition of manganese to Ni/Al2O3 catalysts can increase the catalyst surface area and average pore volume, but decrease NiO crystallite size, leading to higher activity and stability. The effects of reaction temperature, pressure and weight hourly space velocity (WHSV) on carbon oxides conversion and CH4 formation rate were also studied. High carbon oxides conversion, CH4 selectivity and formation rate were achieved at the reaction temperature range of 280 300℃.     

Microcalorimetric Adsorption of Alumina Oxide Catalysts for Combination of Ethylbenzene dehydrogenation and carbon Dioxide Shift-reaction

Styrene (STY) is now produced industrially in fairly large quantities by the dehydrogenation of ethylbenzene (EB) using promoted iron oxide catalyst with superheated steam.In this case, small amount of carbon dioxide formed as a by-product was known to inhibit the catalytic activity of commercial catalyst. Recently, there have been some reports which carbon dioxide showed positive effects to promote catalytic activities on the reaction over several catalysts.In this study, we attempted to combine the dehydrogenation of EB to STY with the carbon dioxide shift-reaction. The combine reaction (EB + CO2 → STY + H2O + CO) can be considered as one of the ways of using CO2 resources and can yield simultaneously STY and Carbon oxide.Alumina oxide catalysts such as Al2O3, Na2O/Al2O3 and K2O/Al2O3 were prepared by the usual impregnation method with an aqueous solution of NaNO3 and KNO3, and then calcined at 650℃ for 5 h in a stream of air. The reaction condition is 600℃, flow of CO2 38ml/mon and space velocity (EB) 1.28h-1.     

气凝胶催化剂上甲烷裂解制备的碳纳米管结构特征

采用XRD、TGA、SEM、TEM、 Raman光谱等多种表征手段,考察了Al2O3气凝胶催化剂上甲烷裂解生长的碳纳米管的结构特征.制得的碳纳米管形态单一,为管径均匀、管壁光滑的中空纳米管,平均直径在10～20 nm.碳纳米管的比表面积较大,具有较强的抗氧化能力,其结构的长程有序度较石墨低.由碳纳米管的Raman光谱分析可知,碳纳米管存在碳层缺陷和无定形碳.当反应温度升高或甲烷浓度下降时,碳纳米管石墨化程度逐渐提高.     

TiO2-Al2O3复合氧化物载体焙烧温度对Au-Pd催化剂加氢脱硫性能的影响

 采用溶胶-凝胶法制备了介孔TiO2-Al2O3复合氧化物载体,考察了载体的焙烧温度对负载型Au-Pd双金属催化剂加氢脱硫性能的影响,并采用X射线衍射、吸附吡啶的程序升温脱附、程序升温还原、红外光谱和N2物理吸附等技术对载体及催化剂进行了表征. 结果表明,不同温度焙烧的TiO2-Al2O3复合载体都具有介孔结构,其中773 K焙烧制得的TiO2-Al2O3复合载体的比表面积和孔容较大, B酸中心较多,以其为载体的Au-Pd 催化剂具有较好的加氢脱硫活性. 表征结果表明, 773 K焙烧制得的Au-Pd/TiO2-Al2O3催化剂中Au-Pd活性组分与载体的相互作用较强,催化剂上形成的AuxPdy合金的晶粒较小且数量较多,催化剂的酸量和活性组分的分散度较大,并且其上进行的加氢脱硫反应的活化能较低,这些因素均有利于催化剂活性的提高.