反应条件对Ni-CaO-ZrO2催化剂上CH4-CO2重整反应及积炭的影响

用共沉淀法制备了Ni-CaO-ZrO₂催化剂,并将其用于CH₄-CO₂重整反应。考察了反应温度、空速和反应物配比对催化剂性能和积炭的影响。通过热力学计算和实验表征研究发现,反应条件对CH₄-CO₂重整反应结果和积炭有重要的影响。由于高温条件同时有利于CH₄裂解和碳物种的及时消除,升高温度可以提高催化剂的活性和稳定性。增大空速则使CH₄的转化率和消碳反应的速率均降低,导致积炭量增加。同时,反应物配比对催化剂表面的积炭量也有很大影响;稍高的CO₂/CH₄摩尔比有利于抑制CH₄-CO₂重整反应过程中的积炭。     

基于程序升温氢化表征的Ni-Al2O3催化剂上CO2-CH4重整反应积炭研究

采用水热沉积法制备Ni-Al₂O₃催化剂,用于CO₂-CH₄重整反应;基于程序升温氢化（TPH）表征,研究了反应时间、温度、原料气CO₂/CH₄比例和空速等因素对CO₂-CH₄重整反应过程中Ni-Al₂O₃催化剂上表面积炭行为的影响。结果表明,表面积炭是导致催化剂重整反应失活的重要原因。随反应时间的延长,催化剂表面积炭量增多,虽未成比例增加,但其TPH峰温有向高温方向移动的趋势,表明所积之炭的石墨化程度增加。反应温度和空速对催化剂表面积炭也有一定影响,且空速的影响更大。另外,由于CO₂消炭反应（CO₂+C=2CO）的存在,CO₂/CH₄比例对表面积炭的影响也很大。CO₂/CH₄比例太低,不能明显抑制积炭;随着CO₂/CH₄比例增加,积炭将得到有效抑制,但CO₂/CH₄比例过高,CO₂在产物中的分离和回收再利用将使成本增加。     

Ni/CeO2-Al2O3催化剂上CH4-CO2转化积炭性能的研究

采用脉冲微量反应技术研究了添加n型半导体氧化物CeO₂对Ni基催化剂上CH₄积炭/CO₂消炭性能的影响,用TPR,XPS和氢吸附技术对催化剂进行了表征.结果表明,活性金属原子Ni与半导体氧化物CeO₂之间存在金属-半导体相互作用(MScI),CeO₂的添加提高了活性原子Ni⁰的d电子密度,在一定程度上抑制了CH₄分子中C-Hσ电子向d轨道的迁移,降低了CH₄裂解积炭活性;可加强Ni⁰原子d轨道向CO₂空反键π轨道的电子迁移,促进CO₂分子的活化,提高CO₂的消炭活性,使Ni/CeO₂-Al₂O₃催化剂具有较强的抗积炭性能.     

制备方法对甲烷干重整催化剂Ni/La2O3/Al2O3结构及性能的影响

采用浸渍法及蒸发法制备了Ni/La₂O₃/Al₂O₃催化剂,考察了制备方法对其结构及甲烷干重整催化性能的影响。通过XRD、H₂ TPR、BET、TEM、TG-DSC等方法对催化剂进行了表征。结果表明,浸渍法制备的催化剂具有较好的Ni分散性、更均匀的粒径分布,较大的比表面积及更优的孔结构,从而具有更好的Ni抗烧结能力及抗积炭性。浸渍法制备的催化剂平均积炭速率很低,约为0.6737mg/(g_cat·h),相当于蒸发法制备催化剂的21%。活性测试结果表明,浸渍法制备的催化剂上CH₄、CO₂转化率及H₂、CO选择性比蒸发法制备的催化剂分别高约5%、10%及4%、3%,具有更好的稳定性。     

载体形貌对Ni3Fe/CeO2催化剂甲烷干重整反应性能的影响

通过改变水热法条件合成了不同形貌CeO₂载体(棒状CeO₂-R、立方体CeO₂-C和多面体CeO₂-P),并用浸渍法制备了Ni₃Fe/CeO₂催化剂,继而研究了不同载体形貌Ni₃Fe/CeO₂催化剂对其甲烷干重整反应性能的影响。采用X射线衍射、N₂吸附-脱附、透射电镜、拉曼光谱、X射线光电子能谱、热重等对反应前后催化剂结构进行表征。结果表明,Ni₃Fe/CeO₂-R具有较大比表面积和较高的氧空位浓度,在甲烷干重整反应中表现出了优异的催化反应活性。800℃时,CH₄和CO₂的转化率分别为82%和91%,且反应10 h性能稳定并且其积炭石墨化程度较低。同时,通过CeO₂-R载体氧空位对CO₂活化,有效抑制了对亲氧性Fe物种的过度氧化行为,反应前后催化剂Ni_...     

制备条件对Ni/ZrO2-SiO2催化剂煤气甲烷化的影响

采用浸渍法制备了ZrO₂-SiO₂复合载体和Ni质量分数为6%的Ni/ZrO₂-SiO₂催化剂,考察了载体制备时浸渍溶液pH值、焙烧温度和催化剂制备时的焙烧温度对Ni/ZrO₂-SiO₂催化剂煤气甲烷化反应性能的影响。采用X射线衍射、程序升温还原和扫描电子显微镜等方法对催化剂进行了表征。结果表明,载体浸渍溶液pH值为8.0～9.0, 载体焙烧温度为550 ℃,催化剂焙烧温度为450 ℃时,Ni/ZrO₂-SiO₂催化剂在煤气甲烷化反应中显示了最优的催化性能,CO转化率100%,CO₂转化率1.8%,CH₄生成速率16.6 mmol/(h·g)。进一步表征发现,制备ZrO₂-SiO₂复合载体时,增大浸渍溶液的pH值有利于形成粒径较小的亚稳态四方晶相ZrO₂,可见四方晶相ZrO₂更有利于甲烷化反应;载体焙烧温度会影响到NiO粒径的大小和其在催化剂表面的分散,温度过高和过低都会导致NiO粒径大小的不适宜以及分散性的降低;催化剂焙烧温度过高则会导致NiO与载体间的相互作用减弱,NiO分散性降低。     

In/HZSM-5催化剂上CH4选择还原NO机理研究

考察了CH⁴+O₂,NO+CH₄(+O₂)与NO₂+CH₄(+O₂)反应体系中CH₄的转化活性.结果表明,浸渍法制备的In/HZSM₅催化剂上CH₄选择还原NO过程中,NO₂的形成起到了活化甲烷的作用.根据NO和NO₂在In/HZSM₅与HZSM₅样品上的TPD及IR研究结果,认为在载体HZSM₅的酸性位及In/HZSM₅催化剂的活性中心In位上均可形成NO₂,NO₂与CH₄的反应在In位上进行.     

SiO2和Al2O3负载的Ni基催化剂在甲烷干重整中的催化性能差异

CH₄与CO₂干重整反应对于环境保护和天然气资源的合理利用具有重要意义。SiO₂和Al₂O₃是适用于甲烷干重整反应的两种典型的催化剂载体。为了阐明这两种载体对催化剂性能的影响,本研究采用等体积浸渍法制备了Ni/Al₂O₃和Ni/SiO₂催化剂,并利用BET、TEM、H₂-TPR、XRD、TG和Raman等技术对还原和反应后的催化剂进行了表征。结果表明,由于载体的性质不同,Ni基催化剂在甲烷干重整中的催化性能也不同。Ni/SiO₂催化剂的初始活性较高,但由于其金属-载体相互作用较弱,催化稳定性较差,在800℃下反应15h其催化活性急剧下降;较弱的金属-载体相互作用使得Ni/SiO₂催化剂上的Ni颗粒较大,有利于积炭前驱物种的生成,导致催化剂快速失活。而对于Ni/Al₂O₃催化剂,金属-载体相互作用较强,Ni颗粒较小,但由于Ni与Al₂O₃生成了NiAl_xO_y物种,有效活性位减少,其催化活性相对较低,但催化稳定性较好,干重整反应进行50h其活性保持稳定;Ni与Al₂O₃之间较强的相互作用有利于形成小且稳定的Ni粒子,能减少积炭,因而具有优异的催化稳定性。     

理论空燃比天然气汽车尾气中H2O和O2对CH4与NO反应的影响

共沉淀法制备CeZrYLa+LaAl 复合氧化物载体, 等体积浸渍法制备了Pt 催化剂, 用于研究理论空燃比天然气汽车(NGVs)尾气净化反应中CH₄与NO的反应规律. 并考察了10% (体积分数, φ)H₂O和计量比O₂对CO₂存在时的CH₄+NO反应的影响. 结果表明: 对于不同条件下的NO+CH₄反应, 主要生成N₂和CO₂, 高温区有CO生成. 低温区无O₂时可以生成N₂O, 有O₂时可以生成NO₂; 添加10% (φ)的H₂O后, CH₄ 转化活性降低, NO转化活性基本不变, 这是由于H₂O减弱了CH₄与CO₂的重整反应, 但是对CH₄与NO的反应基本没有影响; 添加计量比的O₂后, CH₄转化活性提高, 而NO转化活性降低, 这是由于O₂和NO之间存在竞争吸附, CH₄被O₂氧化为主要反应, 从而减弱了NO的转化; 同时添加计量比的O₂和10% (φ) H₂O, CH₄与CO₂的重整反应受到抑制,CH₄与NO的反应、甲烷蒸汽重整反应和甲烷被O₂氧化反应同时发生, CH₄和NO的转化活性均提高.     

In-Co二元金属氧化物上CO2催化加氢反应的选择性转变:催化反应的机理和构效关系

采用催化加氢的方式将CO₂转化为甲醇,既可以减少CO₂排放,又制备了化学品,该反应具有重要的研究意义.氧化铟(In₂O₃)作为CO2加氢制甲醇催化剂,由于其较高的CO₂活化能力和甲醇选择性,被科研工作者广泛研究.其中,将具有良好解离H2能力的过渡金属元素引入In₂O₃(M/In₂O₃)是有效提高催化剂性能的策略之一,然而,M/In₂O₃体系催化CO₂加氢反应机理及活性位点仍不清楚.本文引入Co制备了In-Co二元金属氧化物催化剂应用于CO2加氢制甲醇,结果表明,相较于In₂O₃,In-Co催化剂性能有很大提升,其中In1-Co₄催化剂上甲醇时空产率(9.7 mmol·g_cat^-1 h^-1)是In₂O₃(2.2 mmol·g_cat^-1 h^-1)的近5倍(反应条件:P=4.0 MPa,T=300℃,GHSV=24000 cm³ _STP g_cat^-1 h^-1,H2/CO₂=3).值得注意的是,尽管Co是金属元素的主体,In-Co催化剂中Co催化CO₂甲烷化的活性受到明显抑制.本文还通过多种技术系统研究了催化剂结构与反应选择性转变间的关系.采用电感耦合等离子体发射光谱、粉末X射线衍射、拉曼光谱、X射线光电子能谱和透射电子显微镜等对催化剂结构以及表面性质进行了表征.结果表明,在H₂还原气氛诱导下,In-Co催化剂表面发生重构,形成以CoO为核,以In₂O₃为壳的核壳结构,其在高压反应后仍能保持稳定;更重要的是,该核壳结构可以显著增强In-Co催化剂吸附及活化CO₂的能力.CO₂加氢反应动力学研究表明,Co催化剂上H₂分压对CO₂加氢为零级反应,而H₂分压在In-Co上的反应级数为正数;In-Co催化剂上,CO₂分压的反应级数接近于零,表明CO₂及其衍生物在In-Co的表面吸附饱和,但在纯Co上,则不会发生这种饱和吸附.通过原位DRIFTS研究了催化反应路径和关键中间物种的吸附及反应行为,发现CO₂加氢在纯Co和In-Co上的催化机理均遵循甲酸盐路径.在该催化路径中,CO₂首先加氢为甲酸盐(*HCOO)物种,随后加氢为甲氧基(*CH₃O).*CH₃O在Co催化剂上进一步加氢生成CH₄,而*CH₃O在In-Co催化剂上则会脱附生成CH₃OH.根据表征结果,本文认为,在还原性气氛下,In-Co发生了重构并生成表面富In₂O₃的核壳状结构,显著提高了催化剂对CO₂和含碳物种的吸附能力.Co和In-Co催化剂对CO₂加氢反应选择性的差异归因于催化剂对CO₂和对*HCOO等含碳中间物种的吸附稳定性不同.CO₂及其衍生的含碳中间物种在In-Co催化剂上的吸附能力比在Co催化剂上强,形成了较合适的催化剂表面C/H比,从而使*CH₃O能够脱附为CH₃OH,而不是进一步加氢为CH₄.综上,本文研究为高活性In-Co催化剂体系在CO₂加氢反应中的催化机理及行为提供了解释,为金属-氧化铟(M-In₂O₃)催化剂体系的设计提供了参考.     

甲烷部分氧化制合成气Ni/MgO和Ni-MgO/MgO催化剂的研究

甲烷氧化偶联制乙烷、乙烯以及甲烷选择氧化制甲醇、甲醛等反应 ,因其转化率和收率低 ,故短期内无法实现工业化 .目前 ,工业上应用甲烷蒸汽转化制合成气 ,进而合成氨等化工产品 .甲烷蒸汽转化制的合成气 ,其 H2 /CO≥ 3,不适用于甲醇合成和 F- T合成 .而甲烷部分氧化制的合成气 ,其H2 /CO≤ 2 ,因而最适合用于甲醇合成和 F- T合成 ,故近 1 0年来倍受科学家的关注[1 ,2 ] .在 CH4部分氧化制合成气中 ,钌、铑、钯、铂等贵金属催化剂的活性高、选择性好、稳定性好[1 ] ,但价格昂贵 (负载量以 1 2 %～ 4 0 %为佳 ) ,因而难以实现商品化 .N…     

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…     

Methane Decomposition over Ni/α-Al2O3 Promoted by La2O3 and CeO2

The decomposition of methane on Ni/a-Al2O3 modified by La2O3 and CeO2 with differ-ent contents has been investigated and the ralationship between methane decomposition and removal of carbon by CO2 over these catalyst has also been studied by pulse-chromatography. The catalysts were characterized by TPR and XRD. It was shown that Ni/a-Al2O3 could be promoted by adding La2O3, and the carbon species produced over this catalyst was activated and eliminated by CO2. But CeO2 would suppress the decomposition of methane over Ni crystallite. Both La2O3 and CeO2 can inhibit aggregation of the Ni particles. Decomposition of methane over the Ni-based catalysts is structure sensitive to a certain extent.     

Methane Decomposition over Ni/α-Al_2O_3 Promoted by La_2O_3 and CeO_2

The decomposition of methane on Ni/a-Al2O3 modified by La2O3 and CeO2 with different contents has been investigated and the ralationship between methane decomposition and removal of carbon by CO2 over these catalyst has also been studied by pulse-chromatography. The catalysts were characterized by TPR and XRD. It was shown that Ni/a-Al2O3 could be promoted by adding La2O3, and the carbon species produced over this catalyst was activated and eliminated by CO2. But CeO2 would suppress the decomposition of methane over Ni crystallite. Both La2O3 and CeO2 can inhibit aggregation of the Ni particles. Decomposition of methane over the Ni-based catalysts is structure sensitive to a certain extent.     

Rh doping effect on coking resistance of Ni/SBA-15 catalysts in dry reforming of methane

A series of SBA-15 supported bimetallic Rh–Ni catalysts with different weight ratio of Rh/Ni in the range of 0–0.04 were prepared for carbon dioxide reforming of methane. The doping effect of Rh on catalytic activity as well as carbon accumulation and removal over the catalysts was studied. The characterization results indicated that the addition of a small amount of Rh promoted the reducibility of Ni particles and decreased the Ni particle size. During the dry reforming reaction, the carbon deposition was originated from CH4 decomposition and CO disproportionation. The Rh–Ni catalyst with small metallic particle size inhibited the carbon formation and exhibited high efficiency in the removal of coke. In comparison with bare Ni-based catalyst, the Rh–Ni bimetallic catalysts showed high activity and stability in the dry reforming of methane.     

TAP studies of ammonia decomposition over Ru and Ir catalysts

The Temporal Analysis of Products (TAP) technique has been used to investigate the mechanism involved in the catalytic decomposition of NH(3) over a series of catalysts consisting of activated carbon supported Ru (promoted and non-promoted with Na) and over an activated carbon supported Ir. An extensive study of the role played by both the support and the promoter in the "side reactions" and in the stability and surface lifetime of the NH(x) species has been performed. It was suggested that the N(2) produced during the first steps of the reaction over the activated carbon supported Ru catalysts promoted with Na forms a Na-N-Ru complex at the promoter-transition metal crystallite interface. This study also suggests that the Na promoter prevents the diffusion of hydrogen from the metal to the support via spill-over. A similar effect was observed after the thermal treatment at high temperature of the carbon catalyst support. Finally large differences in multi-pulse TAP results have been detected between Ru and Ir catalysts implying that the NH(3) decomposition reaction mechanism must be different on both metals.     

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.     

Growth of carbon nanotubes on the novel FeCo-Al_2O_3 catalyst prepared by ultrasonic coprecipitation

FeCo-Al2O3 catalyst was prepared by an ultrasonic coprecipitation (UC) method for the growth of carbon nanotubes (CNTs) from catalytic decomposition of methane.Its catalytic performance was compared with that of the FeCo-Al2O3 catalyst counterparts prepared by stepwise impregnation (I) and conventional coprecipitation (C) methods,respectively.The structure and properties of the catalysts and the CNTs as produced thereon were investigated by means of XRD,XPS,TEM and N2 adsorption techniques.It was found that the catalyst prepared by the ultrasonic coprecipitation method was more active,and the yield and purity of the synthesized CNTs were promoted evidently.The XPS results revealed that there were more active components on the surface of the catalyst prepared by the ultrasonic coprecipitation method.On the other hand,N2 adsorption demonstrated that the catalyst prepared by the ultrasonic coprecipitation method conferred larger specific surface area,which was beneficial to dispersion of active components.TEM images further confirmed its higher dispersion.These factors could be responsible for its higher activity for the growth of CNTs from catalytic decomposition of methane.     

催化剂中Cu含量对CVD法制备碳纳米管的影响

本文以溶胶-凝胶法制备了以铜为助剂的Ni/MgO催化剂，X-射线衍射(XRD)表明，经400 ℃氢气处理，催化剂中只有部分镍被还原，原因是NiO和MgO间存在强相互作用，形成固溶体。XRD和程序升温还原(TPR)表明，加入铜促进了镍的还原。CO化学吸附得出，随着催化剂中铜含量的增加，还原后催化剂表面镍原子数目增多，因此，催化剂的活性和反应寿命增加，C₂H₄裂解生成碳纳米管(CNT)的产率随之增加；但是，铜含量过高会引起催化剂表面镍颗粒增大，导致产物中纳米碳纤维（CNF）量增多，CNT量减少。对于约50% Ni/MgO催化剂，铜的最佳含量为4%～6%，此时得到的CNT产率最高，达36 g·g^-1，质量较好(纯度高、管径均匀、石墨化程度高)。     

Growth of carbon nanotubes on the novel FeCo-Al2O3 catalyst prepared by ultrasonic coprecipitation

FeCo-Al_2O_3 catalyst was prepared by an ultrasonic coprecipitation (UC) method for the growth of carbon nanotubes (CNTs) from catalytic decomposition of methane. Its catalytic performance was compared with that of the FeCo-Al_2O_3 catalyst counterparts prepared by stepwise impregnation (I) and conventional coprecipitation (C) methods, respectively. The structure and properties of the catalysts and the CNTs as produced thereon were investigated by means of XRD, XPS, TEM and N_2 adsorption techniques. It was found that the catalyst prepared by the ultrasonic coprecipitation method was more active, and the yield and purity of the synthesized CNTs were promoted evidently. The XPS results revealed that there were more active components on the surface of the catalyst prepared by the ultrasonic coprecipitation method. On the other hand, N_2 adsorption demonstrated that the catalyst prepared by the ultrasonic coprecipitation method conferred larger specific surface area, which was beneficial to dispersion of active components. TEM images further confirmed its higher dispersion. These factors could be responsible for its higher activity for the growth of CNTs from catalytic decomposition of methane.