Screening of MgO——and Ce02-Based Catalysts for Carbon Dioxide Oxidative Coupling of Methane to C2＋ Hydrocarbons

The catalyst screening tests for carbon dioxide oxidative coupling of methane (CO2-OCM)have been investigated over ternary and binary metal oxide catalysts.The catalysts are prepared by doping MgO-and CeO2-based solids with oxides from alkali(Li2O),alkaline earth (CaO),and transition metal groups (WO3 or MnO).The presence of the peroxide (O2^2-)active sites on the Li2O2,revealed by Raman spectroscopy,may be the key factor in the enhanced performance of some of the Li2O/MgO catalysts.The high reducibility of the CeO2 catalyst,an important factor in the CO2-OCM catalyst activity,may be enhanced by the presence of manganese oxide species. The manganese oxide species increases oxygen mobitity and oxygen vacancies in the CeO2 catalyst.raman and Fourier Transform Infra Red (FT-IR)spectroscopies revealed the presence of lattice vibrations of metal-oxygen bondings and active sites in which the peaks carresponding to the buld crystalline structures of Li2O,CaO,WO2 and MnO are detected.The performance of 5%MnO/15?O/CeO2 catalyst is the most potential among the CeO2-based catalysts,although lower than the 2%Li2O/MgO catalyst.The 2%Li2O/MgO catalyst showed the most promising C2 hydrocarbons selectivity and yield at 98.0%and 5.7%,respectively.     

Screening of MgO- and CeO_2-Based Catalysts for Carbon Dioxide Oxidative Coupling of Methane to C_(2+) Hydrocarbons

The catalyst screening tests for carbon dioxide oxidative coupling of methane (CO2-OCM) have been investigated over ternary and binary metal oxide catalysts. The catalysts are prepared by doping MgO- and CeO2-based solids with oxides from alkali (Li2O), alkaline earth (CaO), and transition metal groups (WO3 or MnO). The presence of the peroxide (O2-2) active sites on the Li2O2, revealed by Raman spectroscopy, may be the key factor in the enhanced performance of some of the Li2O/MgO catalysts. The high reducibility of the CeO2 catalyst, an important factor in the CO2-OCM catalyst activity, may     

助剂对超细CuO－ZnO－SiO_2催化剂性质和CO_2加氢反应性能的影响

研究了９种助剂对用于ＣＯ２加氢反应的超细ＣｕＯ－ＺｎＯ－ＳｉＯ２催化剂性能的影响，并进行了ＸＲＤ和ＴＰＲ表征．结果表明，助剂影响超细催化剂的性质和催化性能，ＴｉＯ２、ＣｅＯ２、ＭｇＯ和Ｌａ２Ｏ３是ＣＯ２加氢合成甲醇的超细ＣｕＯ－ＺｎＯ－ＳｉＯ２催化剂体系的优良助剂．在含有不同助剂的ＣｕＯ－ＺｎＯ－ＳｉＯ２催化剂体系内存在ＣｕＯ和ＺｎＯ晶相，但除ＣｅＯ２以外，其它的助剂都可能以微晶或无定型的形式存在．ＴＰＲ研究表明，添加的助剂除ＣｅＯ２以外，都使超细ＣｕＯ－ＺｎＯ－ＳｉＯ２催化剂的还原温度提高，而且助剂对ＣｕＯ－ＺｎＯ－ＳｉＯ２催化剂活性的影响，按照助剂对ＣｕＯ－ＺｎＯ－ＳｉＯ２催化剂还原温度的影响进行了探讨     

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.     

氧化铈形貌对Au/CeO2催化剂催化氧化CO反应活性的影响

采用水热合成法制备了形貌规则的纳米氧化铈颗粒,分别为棒状、立方体和多面体,通过溶胶沉积法将金颗粒沉积到不同形貌氧化铈表面制得了Au/CeO2催化剂.考察了催化剂载体的不同形貌对CO催化氧化反应活性的影响.实验结果表明,棒状(110 100)和多面体(111 100)氧化铈作为载体时的催化剂活性比立方体(100)作为载体时的活性高.在低温段,多面体氧化铈作为载体的催化剂表现出较高活性,而在高温范围,棒状氧化铈作为载体的催化剂的催化活性最好.     

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.     

用于水蒸气重整生物质热解焦油的镍基催化剂的发展(英文)

Nickel catalysts are effective for the steam reforming of tar derived from biomass pyrolysis,but the improvement is needed in terms of activity,stability,suppression of coke deposition and aggregation,and regeneration.Our recent development of Ni-based catalysts for the steam reforming of tar is reviewed including the modification with CeO2(or MnO),trace Pt,and MgO.The role of additives such as CeO2,MnO,Pt,and MgO is also discussed.     

Effect of CeO2 preparation method and Cu loading on CuO/CeO2 catalysts for methane combustion

CeO2 was synthesized by sol-gel, hydrothermal, nitrate thermal decomposition methods, respectively, and used as support to prepare CuO/CeO2 catalysts. According to characterization and reaction results, preparation method of CeO2 had a great influence on the physicochemical properties and activities of CuO/CeO2 catalysts. CuO with high dispersion and strong interaction with CeO2 was highly active in methane combustion, while CuO particles less associated with CeO2 showed less activity. The CuO catalyst supported on CeO2 which was prepared via nitrate thermal decomposition method showed the largest area, the smallest particle size, the highest dispersion of copper species and strong support metal interactions. Therefore, it presented the highest redox ability and activity for methane combustion. Activities of the catalysts with different copper content kept increasing until 5% Cu loading and from then on kept constant. Moreover, methane conversion decreased as methane space velocities increased on CuO/CeO2 catalyst. Addition of CO2 to the feed did not produce a significant effect on the catalytic activity, but the presence of H2O provoked a remarkable decrease on the activity of CuO/CeO2 catalyst.     

CH4-CO2 reforming to syngas over Pt-CeO2-ZrO2/MgO catalysts: Modification of support using ion exchange resin method

Pt-CeO2-ZrO2/MgO (Pt-CZ/MgO) catalysts with 0.8 wt% Pt, 3.0 wt% CeO2 and 3.0 wt% ZrO2 were prepared by wet impregnation method. Support MgO was obtained using ion exchange resin method or using commercial MgO. XRD, BET, SEM, TEM, DTA-TG and CO2-TPD were used to characterize the catalysts. CH4-CO2 reforming to synthesis gas (syngas) was performed to test the catalytic behavior of the catalysts. The catalyst Pt-CZ/MgO-IE(D) prepared using ion exchange resin exhibits more regular structure, smaller and more unique particle sizes, and stronger basicity than the catalyst Pt-CZ/MgO prepared from commercial MgO. At 1073 K and atmospheric pressure, Pt-CZ/MgO-IE(D) catalyst has a higher activity and greater stability than Pt-CZ/MgO catalyst for CH4-CO2 reforming reaction at high gas hourly space velocity of 36000 mL/(g·h) with a stoichiometric feed of CH4 and CO2. Activity measurement and characterization results demonstrate that modification of the support using ion exchange resin method can promote the surface structural property and stability, therefore enhancing the activity and stability for CH4-CO2 reforming reaction.     

特定碱性MgO纳米晶暴露晶面上铁基催化剂及其费-托合成反应的研究

本研究采用等量浸渍法、化学沉淀法和超声浸渍法合成了一系列具有良好外露晶面的Fe/MgO催化剂。采用X射线粉末衍射、高分辨透射电子显微镜、CO₂程序升温脱附、H₂程序升温还原、X射线光谱学和N₂物理吸附等物理化学方法对催化剂进行了表征。MgO纳米晶载体的碱性会影响费-托合成产物的选择性。在超声浸渍过程中,MgO纳米晶载体的碱性得到了保持。研究结果显示,Fe/MgO催化剂的碱性会提高CO解离速率和产物中烯烃的选择性。此外,相比于MgO（100）晶面,MgO（111）晶面负载铁基催化剂具有更高的活性（TOF）和烯烃选择性。MgO（111）晶面上更有利于CO的吸附,抑制二次加氢反应,提高产物中烯烃的收率。     

CeO2修饰的Pt/Ni催化剂在碱性溶液中对乙醇电催化氧化性能的增强

有机小分子直接燃料电池具有高能量密度和转换效率、易贮存及运输方便等优点.在过去几十年,有机小分子化合物尤其是乙醇的电催化氧化引起了研究者的关注,高活性和稳定性及低价格的电催化剂的设计和制备一直是乙醇燃料电池的研究热点.本文采用复合电沉积方法制备了Ni和CeO2复合镀层,然后利用Ni置换铂前驱体中Pt的方法制备了纳米CeO2修饰的Pt/Ni电催化剂(Pt/Ni-CeO2).采用X射线衍射(XRD)、扫描电子显微镜(SEM)及能谱仪(EDS)等手段表征了所制样品的组成和相结构、表面形貌及组成成份.XRD结果表明,所制Pt/Ni催化剂主要是PtNi合金相结构.与Pt/Ni相比,Pt/Ni-CeO2催化剂的XRD峰强明显变弱,表明纳米CeO2修饰的Pt/Ni电催化剂的结晶性较差或者其晶体颗粒较小.这可能是由于CeO2的共沉积阻止了Ni纳米颗粒的进一步生长或团聚.当电镀液中CeO2含量为50和100 mg/L时,所制Pt/Ni-CeO2催化剂样品Pt/NiCe1和Pt/NiCe2的XRD谱上未观察到CeO2相关的衍射峰,这主要可归因于催化剂中沉积的CeO2量少或其高度分散.随着电镀液中CeO2浓度进一步增大到200 mg/L时,在Pt/Ni-CeO2催化剂(Pt/NiCe4)的XRD谱上出现了CeO2相关的衍射峰.这表明采用复合电沉积-化学还原法可以成功制备CeO2修饰的Pt/Ni电催化剂.SEM结果显示,所制催化剂都是由团聚状态的纳米颗粒组成,并且Pt/NiCe2表现出比Pt/Ni更开放的微结构,从而有利于反应物扩散至催化剂内部.该结果进一步表明共沉积的CeO2对所制Pt/Ni催化剂微结构的影响.此外,EDS结果也证实成功制备了CeO2修饰的Pt/Ni电催化剂.采用多次循环伏安、电流时间曲线和电化学阻抗谱(EIS)等手段研究了所制电催化剂的电化学性能.与Pt/Ni相比,Pt/Ni-CeO2催化剂表现出更好的电催化氧化乙醇活性和稳定性,这可能与CeO2的贮氧特性及其共沉积增大了电极的粗糙度有关.红外光谱测试结果表明,在CeO2修饰的Pt/Ni电催化剂催化氧化乙醇过程中,CH3COO?可能是乙醇氧化的主要产物.在所制催化剂中,CeO2含量影响其电催化氧化乙醇性能.循环伏安和电流时间曲线测试结果表明,随着催化剂中CeO2含量增大,催化剂活性先增加后减弱.电化学阻抗谱结果表明,随着CeO2含量增大,CeO2修饰的Pt/Ni电催化剂的接触电阻先增大后变小再变大;而电荷转移电阻不断变小.在电解液中含有100 mg/L CeO2时所制电催化剂(Pt/NiCe2)具有最佳的电催化氧化乙醇活性和稳定性.这主要与CeO2的贮氧功能、Pt与CeO2/Ni间的相互作用和其较小的接触电阻和电荷转移电阻有关.该结果可为设计和制备低价格、高活性乙醇燃料电池中的催化剂提供思路.     

CO氧化反应中的二氧化铈晶面效应

二氧化铈(CeO2)因其具有较强的储放氧能力,被用作氧化还原反应的催化材料.自2005年,研究者制备出形貌可控的CeO2纳米棒、纳米立方块和纳米多面体,在CeO2形貌控制及构效关系研究方面取得长足发展.各种结构表征手段包括原位拉曼(in situ Raman)、原位傅里叶变换红外光谱(in situ DRIFTS)、核磁共振(NMR)和电镜等被用来研究不同形貌CeO2的表面结构和在催化反应中的活性差异.一般的活性规律为CeO2纳米棒({110}/{100})>纳米立方块({100})>纳米多面体({111}/{100}).近年来,负载型CeO2催化剂因其能稳定分散金属,通过金属-载体相互作用调控界面电子结构并表现出优异的催化活性而引起广泛关注,其中晶面效应在负载型CeO2催化体系中显得较为复杂.铜铈催化剂被认为是非常经济有效的CO氧化催化剂,然而由于制备和测试条件差异导致的CeO2晶面对铜铈催化剂催化CO氧化活性的影响规律并不统一.我们之前的研究工作发现纳米棒CeO2-{110}晶面上的Cu-[Ox]-Ce结构不利于形成Cu((40)),而纳米颗粒CeO2-{111}晶面上的CuOx团簇很容易形成Cu((40)),从而对CO催化氧化极为有利,这与纯载体CeO2的规律并不一致.与此同时,对于铜负载的CeO2纳米棒(NR)及纳米立方体(NC)所体现的性质及活性差异缺少系统深入的研究.在上述工作基础上,我们采用沉积沉淀法在CeO2 NR及CeO2 NC上负载1%wt的铜分别得到1Cu CeNR和1Cu CeNC,并对所合成催化剂的结构和吸附性能进行了表征.高分辨透射电镜(HRTEM)照片显示,CeO2纳米棒主要暴露{110}晶面,而CeO2纳米立方体以{100}晶面为主.催化测试结果表明,1Cu CeNC在130℃时CO已完全转化为CO2,而相同温度下1Cu Ce NR只有50%转化.进一步通过氢气程序升温还原(H2-TPR)和一氧化碳程序升温脱附(CO-TPD)分析发现, 1Cu Ce NC催化剂具有较强的还原性且表面氧物种含量高.此外, X射线光电子能谱(XPS)和in situ DRIFTS研究表明, 1Cu Ce NC促进Cu((40))位点生成,导致活性Cu((40))-CO物种增多,这些优异的化学性质导致其具有较高的催化CO氧化活性.     

CeO2含量对Ni-Mn-K/Al2O3多元体水煤气变换催化剂催化性能的影响

以γ-Al2O3为载体，采用二步漫渍法，制备一系列不同CeO2含量的Ni-Mn-K／Al2O3多元体水煤气变换催化剂。采用BET，XRD，TPD和TPR等方法，考察了CeO2含量对催化剂催化性能和结构的影响。结果表明：CeO2的掺杂能显著提高催化剂的水煤气变换活性，其中以掺杂7．5％CeO2提高活性最为显著。CeO2的加入使催化剂的还原温度有所提高，使催化剂捕获H2O分子并使其解离成O和-OH的能力增强，提高了CO的吸附量。此外，CeO2的加入使催化剂的活性中心和活性中心数变化不明显，催化剂的比表面积和孔的分布微小变化并不是改变催化剂活性的主要因素。     

氧化铈负载钌催化剂中钌表面密度对氨合成活性和氢中毒的影响

氨是关系国计民生的大宗化学品,也是氢能源的重要载体.目前,世界合成氨工业每年消耗约2％的世界总能源,并排放超过1％的CO2,节能降耗需求十分迫切,其中的关键在于高性能氨合成催化剂的开发.传统观点认为,B5活性位是钌催化剂上氮解离和氨合成的活性位,当钌粒子尺寸在1.8～2.5 nm时催化剂的B5活性位数量最多,而钌尺寸较小(0.7～0.8 nm)的催化剂几乎没有氨合成活性.本文通过改变钌负载量调变了氧化铈负载钌催化剂的钌表面浓度,证实钌粒子尺寸低于2.0nm时,氧化铈负载钌催化剂也具有较高的氨合成活性.XPS等表征结果证实:钌表面密度低于0.68 Ru nm-2时,钌主要以层状形式存在于氧化铈表面,层状钌与氧化铈紧密接触,电子从氧化铈的缺陷位传递给钌物种,在这种情况下,Ru 3d5/2的结合能有所下降,氮解离能力增强,这有利于提高催化剂的氨合成活性;当钌表面密度约为0.68 Ru nm-2时,钌金属传递电子给氧化铈,此时Ru 3d5/2结合能有所增加;当钌表面密度高于1.4 Ru nm-2后,钌物种优先在层状钌表面聚集成大尺寸钌纳米粒子,此时催化剂中同时存在钌团簇和钌纳米粒子,氧化铈载体对钌粒子电子性质的影响减弱,因此大尺寸钌金属颗粒Ru 3d5/2结合能又有所下降.另一方面,氢分子会在氧化铈表面形成均裂产物(两个OH基团)或异裂产物(Ce-H和OH).同时氢分子还会在0价钌金属表面解离形成氢原子,并进一步溢流到氧化铈表面与氧原子作用形成羟基.钌活性位上的氢物种比氧化铈中的氢更容易脱附,因此氧化铈中钌的存在不仅可以增强其氢吸附量,还降低了氢物种的吸附强度.当钌表面密度低时,氧化铈与钌的相互作用较强,催化剂中的氢物种容易溢流到氧化铈中形成羟基基团,此时催化剂的氢吸附能力增强,氢中毒问题较显著.当钌表面密度较高时,氢原子在大尺寸钌颗粒上移动、反应和脱附,因此催化剂的氢中毒问题也得到显著缓解.总之,对于氧化铈负载钌催化剂,氧化铈与钌金属之间的电子相互作用以及其吸附性质都会影响催化剂的氨合成活性,因此钌表面密度低于0.31 Ru nm-2以及约为2.1 Ru nm-2时,催化剂都展现出了较高的氨合成活性.本文将为设计制备高性能钌基氨合成催化剂提供理论指导.     

La2O3对CuO/CeO2水煤气变换反应催化剂微观结构及催化性能的影响（英文）

以La2O3为助剂,采用共沉淀法制备了具有良好催化活性和热稳定性的CuO/CeO2-La2O3水煤气变换反应催化剂,其中,当La2O3含量为2wt%时,催化剂的催化性能最为优异.同时运用X射线衍射、N2吸附-脱附、Raman光谱、程序升温还原等手段,研究了不同含量的La2O3对CuO/CeO2催化剂微观结构及催化性能的影响.结果表明,La2O3助剂进入了载体CeO2的晶格并对CuO/CeO2催化剂的微观结构和催化性能产生了直接影响,适量La2O3的添加可以抑制CuO和CeO2晶格的长大、增强CuO与CeO2间的相互作用、提高催化剂的比表面积、促进CeO2载体中生成更多的氧空位,CuO/CeO2催化剂的催化活性和热稳定性也明显改善.     

CeO2负载的Cu, Ir和Pd催化剂上的醇转移脱氢反应

 研究了CeO2负载的Cu, Ir和Pd催化剂上的醇转移脱氢反应. 利用催化剂体系脱氢和加氢功能的偶合,在较温和的反应条件下实现了二级脂肪醇的高选择性转移脱氢. 其中, Ir/CeO2催化剂表现出较高的催化活性,其TOF值达16.0 h-1.     

CO Selective Oxidation in Hydrogen-Rich Gas over Copper-Series Catalysts

The performances of CO selective oxidation in hydrogen-rich gas over four catalytic systems of CuO/ZrO2, CuO/MnO2, CuO/CoO and CuO/CeO2 were compared. The reducibility of these catalysts and the effect of CuO and CeO2 molar ratio of CuO/CeO2 catalysts on the activity of selective CO oxidation are investigated by XRD and TPR methods. The results show that the catalysts with the exception of CuO/ZrO2 have the interactions between CuO and CoO, CeO2 or MnO2, which result in a decrease in the reduction temperature. Among the catalysts studied, CuO/ZrO2 catalyst shows the lowest catalytic activity while CuO/CeO2 catalyst exhibits the best catalytic performance. The CuO(10%)/CeO2 catalyst attains the highest CO conversion and selectivity at 140 and 160℃. The addition of 9% H2O in the reactant feed decreases the activity of CuO/CeO2 catalyst but increases its CO selectivity.     

Comparative study of CeO2 and doped CeO2 with tailored oxygen vacancies for CO oxidation

We report on the preparation and characterization of CeO(2) nanofibers (CeO(2)-NFs) and nanocubes (CeO(2)-NCs), as well as Sm- and Gd-doped CeO(2) nanocubes (Sm-CeO(2)-NCs and Gd-CeO(2)-NCs), synthesized by a simple hydrothermal process for CO catalytic oxidation. The samples were characterized by X-ray diffraction (XRD), Brunauer-Emmett-Teller (BET), X-ray photoelectron spectroscopy (XPS), transmission electron microscopy (TEM), Raman spectroscopy, and photoluminescence spectroscopy. Their oxygen-storing capacity (OSC) was examined by means of hydrogen temperature-programmed reduction (H(2)-TPR) and oxygen pulse techniques. Their catalytic properties for CO catalytic oxidation were comparatively investigated. The results showed that the CeO(2)-NFs possessed a higher catalytic activity compared to the CeO(2)-NCs because of their smaller size and the greater number of oxygen vacancies. The activity of the Sm-CeO(2)-NCs was higher than that of the CeO(2)-NCs due to an increase in the number of oxygen vacancies, which results from the substitution of Ce(4+) species with Sm(3+) ions. In contrast, Gd doping had a negative effect on the CO catalytic oxidation due to the special electron configuration of Gd(3+) (4f(7)). Our work demonstrates that the oxygen vacancies in pure CeO(2) and the electron configuration of the dopants in doped CeO(2) play an important role in CO oxidation.     

CeO2对催化剂银物种及CO氧化性能的影响

采用共浸渍、不同分步浸渍的方法制备了8 wt% Ag/CeO2-SiO2催化剂,运用XRD、UV-Vis、BET等多种手段对催化剂的结构进行表征,考察了其对CO氧化的活性,并初步探讨了助剂CeO2对催化剂结构及活性物种的影响。实验结果表明,添加1 wt% CeO2的8 wt% Ag/SiO2催化剂表现出较好的低温CO催化活性,随后氢气预处理明显提高了催化剂的反应活性。XRD和UV-Vis谱图表明少量的CeO2（1 wt%）有利于金属银物种的形成,并且能够提高Ag粒子的稳定性,高温处理不易聚集。高CeO2负载量下的催化剂中银物种主要以银簇（ ）形式存在。     

Effect of Addition of Base on Ceria and Reactivity of CuO/CeO2 Catalysts for Low-Temperature CO Oxidation

In this work, we have reported the influence of the addition of base (KOH) on the physicochemical property of ceria synthesized by alcohothermal process, and the alcohothermal mechanism was also put forward. Furthermore, the prepared CeO2 was used as the support to prepare CuO/CeO2 catalysts via the wet impregnation method. The samples were characterized by N2 adsorption-desorption, X-ray powder diffraction (XRD), high resolution transmission electron microscopy (HRTEM), and temperature-programmed reduction by H2 (H2-TPR). The catalytic properties of the CuO/CeO2 catalysts for low-temperature CO oxidation were studied using a microreactor-GC system. The crystal size of CeO2-A was much smaller than that of CeO2-B, and the corresponding copper oxide catalysts exhibited higher catalytic activity than that of the CeO2-B-supported catalysts under the same reaction conditions. The alcohothermal mechanism indicated that KOH plays a key role in determining the physicochemical and catalytic properties of ceria-based materials.