助剂调变对CoO／γ-Al2O3催化性能的影响

采用XRD、TPR和催化活性评价等技术,考察了负载型CoO催化剂的表面特征和其对CH4与CO2重整制合成气反应的催化性能.实验结果表明,采用浸渍法和焙烧温度为400℃时制备的11.0%CoO/γ-Al2O3催化剂,在反应温度为750 ℃和空速(GHSV)为2 500 h-1下,对CH4和CO2转化反应具有最佳的催化初活性,而大量的Co3O4晶粒的存在能导致催化剂因积炭而快速失去活性.CaO、MgO和La2O3助剂的添加能有效地改善其催化剂的抗积炭能力和还原性能,CoO/(CaO-γ-Al2O3)催化剂显示出最佳的催化反应稳定性,在750 ℃、GHSV=2 500 h-1、CH4/CO2原料比为1:1下,连续反应100 h催化剂活性较为稳定.CoO/(CaO-γ-Al2O3)和CoO/γ-Al2O3催化剂的表面特性本质上是不相同的.     

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   

纳米ZrO2/Al2O3复合载体及Ni/ZrO2/Al2O3催化剂的性能研究

 采用溶胶-凝胶法在经过扩孔处理的Al2O3基载体上制备了纳米ZrO2/Al2O3复合载体,并通过浸渍法制备了NiO/ZrO2/Al2O3催化剂. 用XRD,TPR,TPD和N2吸附等技术分别考察了载体和催化剂的结构及表面性能,研究了复合载体对Ni/ZrO2/Al2O3催化CO2重整CH4反应性能的影响. 结果表明,纳米ZrO2/Al2O3复合载体具有较大的比表面积、适宜的孔径分布及稳定的t-ZrO2结构,Ni/ZrO2/Al2O3催化剂具有较好的CO2重整CH4反应活性和稳定性.     

La2O3助剂对CH4部分氧化制氢Ni-Cu/ZrSiO催化剂的影响

用等体积浸渍法制备了ZrO2-SiO2(ZrSiO)表面复合氧化物负载的Ni-Cu双金属催化剂，并用TPR、XPS、IR、TPD及微反技术考察了稀土La2O3助剂对CH4和H2O在Ni-Cu/ZrSiO催化剂表面上的吸附及甲烷部分氧化制氢反应性能的影响。结果表明，加入La2O3助剂使催化剂表面Ni, Cu原子电子云密度增加，CH4和H2O在催化剂表面上的吸附增强；在反应温度450 ℃、进料摩尔比n-CH4∶nO2∶nH2O＝1∶0-5∶2-5以及甲烷空速SV(CH4)＝1 200 h－1的条件下，催化剂Ni-Cu-La2O3/ZrSiO上CH4转化率大于90％，生成H2的选择性高于99％，副产物CO的选择性仅为1.1％。根据实验结果，讨论了La2O3助催化剂的作用机理。     

SnO_2-SiO_2负载Cu、Ni催化剂的CO_2加氢反应性能

采用表面反应改性法制备了SnO2 SiO2 (SnSiO)表面复合物载体 ,用等体积浸渍法制备了SnSiO担载的Cu Ni双金属催化剂。借助BET、XRD、TPR、IR和微反等技术研究了SnSiO及其负载的Ni、Cu双金属催化剂的表面构造、化学吸附及CO2 加氢反应性能。结果表明 :SnSiO是SnO2 单分子层价联于SiO2 表面的复合氧化物 ,仍保持类似SiO2载体的孔结构和比表面 ;SnO2 引入SiO2 表面后可以有效地促进CuO、NiO的还原 ,还原后成为负载在SnSiO载体表面的Cu Ni合金 ;CO2 在负载型Cu Ni合金表面Cu或表面Ni位上发生化学吸附 ,形成线式和剪式吸附态 ;CO2 在催化剂上的加氢反应产物主要是CH3 OH、CH4 、CO和H2 O ,生成CH3 OH的选择性与催化剂组成及反应条件密切相关。Cu Ni催化剂 ,在 0 5MPa ,170℃ ,H2 /CO2 (mol/mol)为 3的条件下 ,CH3 OH的选择性达到 84 6 %。     

CeO2和Pd在Ni/γ-Al2O3催化剂中的助剂作用

采用脉冲微反技术研究了添加n型半导体氧化物CeO2及贵金属Pd对Ni/γ Al2O3催化剂上CH4积炭/CO2消炭反应性能的影响,并运用BET、TPR、CO2 TPSR及氢吸附等技术对催化剂进行了表征.结果表明, n型半导体氧化物CeO2的添加可以降低Ni/γ Al2O3催化剂上CH4裂解积炭活性,提高CO2消炭活性,添加少量贵金属Pd可以进一步改变载体Al2O3、助剂CeO2和活性组分Ni之间的相互作用,从而改善Ni/γ Al2O3催化剂的抗积炭性能.通过Ni Ce Pd/γ Al2O3催化剂上CH4积炭/CO2消炭模型对上述作用机制作出了新的解释.     

CeO2和Pd在Ni/γ-Al2O3催化剂中的助剂作用

采用脉冲微反技术研究了添加n型半导体氧化物CeO2及贵金属Pd对Ni/γ-Al2O3催化剂上CH4积炭/CO2消炭反应性能的影响,并运用BET、TPR、CO2-TPSR及氢吸附等技术对催化剂进行了表征.结果表明,n型半导体氧化物CeO2的添加可以降低Ni/γ-Al2O3催化剂上CH4裂解积炭活性,提高CO2消炭活性,添加少量贵金属Pd可以进一步改变载体Al2O3、助剂CeO2和活性组分Ni之间的相互作用,从而改善Ni/γ-Al2O3催化剂的抗积炭性能.通过Ni-Ce-Pd/γ-Al2O3催化剂上CH4积炭/CO2消炭模型对上述作用机制作出了新的解释.     

ZrO2—SiO2负载Cu—Ni催化剂的CO2加氢反应性能

采用表面反应改性法,制备了ZrO2-SiO2（ZrSiO)表面复合物载体,用等体积浸渍法制备了ZrSiO担载的Cu-Ni双金属催化剂,借助BET、TPR、IR和微反等技术,研究了ZrSiO及其负载的Ni、Cu双金属催化剂的表面构造,化学吸附及催化CO2加氢的反应性能,结果表明,ZrSiO表面主要是价联型结构,ZrO2引入SiO2表面,可以有效地促进CuO和NiO的还原,在ZrSiO负载的Cu-Ni催化剂表面的Cu或Ni位,CO2发生化学 吸附形成线、剪式、卧式吸附态,在该催化剂上CO2的加氢反应产物主要是CH3OH3、CH4、CO和H2O生成CH3OH的选择性与催化剂组成及反应条件密切相关,在适当的条件,CH3OH的选择性大于90％。     

La2O3对Ni-Cu/MgSiO催化剂的甲烷部分氧化制氢反应性能的影响

 用等体积浸渍法制备了MgO-SiO2(MgSiO)复合氧化物负载的Ni-Cu双金属催化剂,采用程序升温还原(TPR),X光电子能谱(XPS),红外光谱(IR),程序升温脱附(TPD)及微反技术考察了稀土La2O3的加入对CH4和H2O在Ni-Cu/MgSiO催化剂表面上的吸附及甲烷部分氧化制氢反应性能的影响. 结果表明,加入La2O3使催化剂表面Ni和Cu原子的电子云密度增加,CH4和H2O在催化剂表面上的吸附增强. CH4与O2和H2O在Ni-Cu/MgSiO催化剂上反应的主要产物为H2和CO2. La2O3的加入有利于提高CH4转化率及H2的选择性,并可提高催化剂稳定性及抗积炭能力. 讨论了La2O3的助催化作用机理.     

K2O助剂对合成碳酸二甲酯用Cu—Ni／MoO3—SiO2催化剂吸附和反应性能的影响

用等体积浸渍法制备了MoO3-SiO2(MoSiO)表面复合氧化物负载的Cu-Ni-K2O催化剂。利用IR,TPR,TPD以及微反技术研究了K2O助剂对CO2和CH3OH在Cu-Ni/MoSiO催化剂表面上吸附和合成DMC（碳酸二甲酯）反应性能的影响。结果表明：K2O助剂的加入,使CO2在催化剂表面吸附强度增加,当K2O含量达Cu-Ni总量的15%时,CO2在催化剂表面上吸附后生成K2CO3;CH3OH在催化剂表面上的解离吸附态（CH3O^- H^ ）的吸附强度减弱;CO2和CH3OH和Cu-Ni-K2O/MoSiO催化剂表面反应主要产物为DMC,H2O,CO和CH2O。随着K2O助剂的加入,反应转化率在10%之前增加,之后下降,DMC选择性稍有提高。副产物（CO和CH2O）的选择性下降。根据实验结果探讨了K2O对催化剂表面活性中心的电荷分布的影响。     

不同制备方法对Ba/MgO催化剂催化甲烷氧化偶联反应性能的影响(英文)

采用ＢＥＴ、ＸＲＤ、ＳＥＭ和ＸＰＳ等方法对Ｂａ／ＭｇＯ催化剂进行了分析,并且对该催化剂对甲烷氧化偶联反应的性能进行了测试。结果表明,制备方法对Ｂａ／ＭｇＯ催化剂的催化性能有很大影响。采用淤浆法制备的Ｂａ／ＭｇＯ催化剂具有合适的比表面积和表面氧物种分布,因此对甲烷转化显示出良好的催化活性。而采用机械混合或浸渍等方法制备的催化剂由于表面不均匀以及表面烧结等原因其活性较差。     

FTIR study of CO adsorption on Rh/MgO modified with Co, Ni, Fe, or CeO2 for the catalytic partial oxidation of methane

The surface state of Rh/MgO catalysts modified with Co, Ni, Fe, or CeO(2) after the reduction and partial oxidation pretreatments as well as during the catalytic partial oxidation of methane has been investigated by FTIR of adsorbed CO. The results of CO adsorption on the reduced catalysts suggest the formation of Rh-M alloy on Rh-M/MgO (M = Co, Ni, Fe) and Rh particles partially covered with reduced ceria on Rh-CeO(2)/MgO. The strength of CO adsorption on Rh/MgO is weakened by the modification with Co, Ni, Fe, or CeO(2). Partial oxidation pretreatment of Rh/MgO leads to a significant decrease in the CO adsorption due to the oxidation of Rh. In contrast, on partially oxidized Rh-M/MgO (M = Co, Ni, Fe) and Rh-CeO(2)/MgO, the preferential oxidation of the surface M atoms or reduced ceria maintains the metallic Rh and preserves the CO adsorbed on the surface Rh atoms. The CO adsorption during the reaction of catalytic partial oxidation of methane on Rh/MgO and Rh-Ni/MgO is similar to that on the reduced catalysts. On the other hand, the CO adsorption during the reaction on Rh-Co/MgO, Rh-Fe/MgO, and Rh-CeO(2)/MgO is different from that on the reduced catalysts, and this is related to the structural change of these catalysts during the reaction.     

氧化镁载体和氧化钡助剂对钌基氨合成催化剂结构和性能的影响

采用不同来源氧化镁(市售MgO-1,合成MgO-2)作为钌基氨合成催化剂载体,浸渍法制备了添加不同BaO助剂含量的Ba-Ru/MgO催化剂,通过X射线衍射(XRD)、热重-量热扫描分析(TG/DSC)、N2-低温物理吸附、透射电镜(TEM)、H2程序升温还原(H2-TPR)和CO2程序升温脱附(CO2-TPD)等手段对其进行了表征,考察了不同来源的MgO和BaO助剂含量对负载型钌基氨合成催化剂的物相结构、织构性质、微观形貌、Ru物种的还原性质和体系酸碱性质以及催化剂的氨合成活性等方面的影响。结果表明,MgO的理化性质对所制备的钌基氨合成催化剂的结构以及氨合成活性有较大影响。MgO-2比表面较大,总碱性位数量较多,负载在其表面的Ru粒子粒径在2 nm左右,nBa∶nRu为1.0时,Ba-Ru(1∶1)/MgO-2催化剂表面的Ru物种易于还原,表面存在的弱碱性位极大地促进了氨合成活性,在400°C时活性达到15.40 L.g-1Ru.h-1(3.0 MPa,5 000 h-1),在相同反应条件下比Ba-Ru/MgO-1催化剂活性更高。     

Nickel catalysts supported on MgO with different specific surface area for carbon dioxide reforming of methane

In this paper, three kinds of MgO with different specific surface area were prepared, and their effects on the catalytic performance of nickel catalysts for the carbon dioxide reforming of methane were investigated. The results showed that MgO support with the higher specific surface area led to the higher dispersion of the active metal, which resulted in the higher initial activity. On the other hand, the specific surface area of MgO materials might not be the dominant factor for the basicity of support to chemisorb and activate CO₂, which was another important factor for the performance of catalysts. Herein, Ni/MgO(CA) catalyst with proper specific surface area and strong ability to activate CO₂ exhibited stable catalytic property and the carbon species deposited on the Ni/MgO(CA) catalyst after 10 h of reaction at 650 °C were mainly activated carbon species.     

MgO/HZSM-5中MgO分散状态和催化性能的关系

以硝酸镁、醋酸镁为前身物,通过浸渍法制备了不同系列MgO/ HZSM-5催化剂,用XRD、XPS方法研究了MgO在HZSM-5上的分散状态,用NH3-TPD方法考察了催化剂的酸性,用常压连续流动微型反应装置考察MgO/ HZSM-5在甲苯甲醇烷基化反应中的催化性能.发现前身物不同,MgO在HZSM-5上的分散状态也不同,催化剂的活性和选择性与MgO分散状态密切相关.MgO负载量相同时,在以硝酸镁为前身物制备的催化剂中,MgO在HZSM-5内外表面均有分散,催化剂的对位选择性较高,而活性较低;在以醋酸镁为前身物制备的催化剂中,MgO较多分布在HZSM-5外表面,催化剂的活性较高,但选择性较低.使用醋酸镁为前身物,通过二次浸渍和高温水汽处理,适当改变MgO在分子筛表面的分布并使孔道窄化,可在活性降低较少的情况下显著提高催化剂对二甲苯选择性.     

Benzylation of aromatic compounds with different crystallites of MgO

Magnesium oxide nanocrystals are shown to be selective catalysts for the benzylation of aromatics with benzyl chloride, in the order xylene > toluene > benzene. Normal polycrystalline MgO is not as effective as the nanomaterials. However, at the highest surface area, normally most reactive MgO samples (aerogel prepared AP-MgO) were poorer catalysts than a hexagonal platelet form (CP-MgO) of lower surface area. During the catalysis, the MgO is partially converted to MgCl(2), but crystal shape differences are not washed out. Rate data, differential thermal analysis, and consideration of crystal shapes and faces suggest that the CP-MgO form is most catalytically active because of optimal adsorption, molecular trafficking, and desorption energies. The AP-MgO apparently adsorbs the reactants too strongly, and thereby this hinders the catalytic process. These results serve as another example of where nanocrystalline shape plays an important role.     

Syntheis of SWNTs over Co-Mo/MgO Nanoporous and using as a catalyst support for selective hydrogenation of syn gas to hydrocarbon

Single-wall carbon nanotubes (SWNTs) with high surface area were synthesized over nanoporous Co-Mo/MgO by a chemical vapor deposition (CVD) method. The SWNTs were used as catalyst support for selective hydrogenation of syngas to hydrocarbons. Here an extensive study of Fischer-Tropsch synthesis (FTS) on CNT-supported cobalt catalysts with different amounts of cobalt loading up to 40 wt% is reported. The catalysts were characterized by different methods including N2 adsorption-desorption, X-ray diffraction, hydrogen chemisorption, inductively coupled plasma (ICP) and temperature-programmed reduction. Enhancement of the reducibility of Co3O4 to CoO, CoO to Coo and small cobalt oxide particles, dispersion of the cobalt, and activity and selectivity of FTS were investigated and compared with a conventional support. The CNT supported catalysts achieve a high dispersion and high loading of the active metal, cobalt in particular, so that the bulk formation of cobalt metal, which tends to occur in conventional support, can be avoided. The results showed that the specific activity of CNT supported catalysts increase significantly (there is a two fold increase in CO Conversion per gram of the active metal) with respect to the conventional supported catalyst.     

Synthesis of SWNTs over nanoporous Co-Mo/MgO and using as a catalyst support for selective hydrogenation of syngas to hydrocarbon

Single-wall carbon nanotubes (SWNTs) with high surface area were synthesized over nanoporous Co-Mo/MgO by a chemical vapor deposition (CVD) method. The SWNTs were used as catalyst support for selective hydrogenation of syngas to hydrocarbons. Here an extensive study of Fischer-Tropsch synthesis (FTS) on CNT-supported cobalt catalysts with different amounts of cobalt loading up to 40 wt% is reported. The catalysts were characterized by different methods including N2 adsorption-desorption, X-ray diffraction, hydrogen chemisorption, inductively coupled plasma (ICP) and temperature-programmed reduction. Enhancement of the reducibility of Co3O4 to CoO, CoO to Coo and small cobalt oxide particles, dispersion of the cobalt, and activity and selectivity of FTS were investigated and compared with a conventional support. The CNT supported catalysts achieve a high dispersion and high loading of the active metal, cobalt in particular, so that the bulk formation of cobalt metal, which tends to occur in conventional support, can be avoided. The results showed that the specific activity of CNT supported catalysts increase significantly (there is a two fold increase in CO Conversion per gram of the active metal) with respect to the conventional supported catalyst.     

不同MgO载体对合成低碳烯烃用铁锰基催化剂的影响

采用共沉淀法、硝酸盐热分解法制备的MgO和商品MgO为载体,使用共浸渍法制备了系列FeMn/MgO催化剂,以CO加氢合成低碳烯烃为模型反应,对不同催化剂的反应性能进行了考察,采用X射线光电子能谱、N2物理吸附、X射线物相分析、程序升温还原等表征技术对催化剂的结构和性能进行了表征。结果表明,采用共沉淀法制备的MgO载体比表面积最大,达到203.5m²/g,以此为载体制备的催化剂取得了最优的CO加氢合成低碳烯烃性能。在340℃、2.0MPa、1600h^-1的反应条件下,CO转化率达到91.36%,C₂⁼～C₄⁼选择性为58.48%。催化剂的比表面积大,活性组分分布均匀且在表面含量高及低温还原性能的明显改善是其具有优异的催化性能的重要原因。     

Selective catalytic reduction of NO by propane over CoO(x)/Al2O3: an investigation of the surface reactions using in situ infrared spectroscopy

The partial oxidation of propane and the mechanism of the selective catalytic reduction (SCR) of NO by C3H8 over CoO(x)/Al2O3 catalysts were investigated using in situ infrared spectroscopy. Emphases are placed on the formation and reactivity of surface oxygenates during the SCR reaction. The SCR reaction starts with partial oxidation of propane to adsorbed acetate and formate. Impregnation of cobalt onto alumina greatly enhanced this reaction. The as-formed acetate acts as an efficient reductant for NO reduction. Surface nitrates (nitrites) are also reactive to propane and to oxygenates generated from C3H8 + O2 reaction. Surface -NCO species are formed over CoO(x)/Al2O3 catalysts. These nitrogen containing organic species are believed to be the direct intermediates in the final formation of N2. On the basis of these investigations, a proposed reaction mechanism explains the formation and roles of all intermediates detected by IR spectroscopy in this study.