CeO2/Co3O4氧载体的制备及其甲烷化学链燃烧性能研究

制备了系列甲烷化学链燃烧用CeO₂/Co₃O₄复合氧载体,采用XRD、H₂-TPR、甲烷程序升温和恒温反应对氧载体进行了表征与评价。研究了不同CeO₂的负载量对复合氧载体的结构、氧化还原性、产物选择性的影响。结果表明,氧化铈的添加不仅降低了氧载体的初始反应温度,还延长了有效反应时间,但铈添加量过高会降低产物CO₂选择性,使甲烷向部分氧化进行。CeO₂(30%)/Co₃O₄氧载体在650 ℃经20次循环后甲烷转化率和CO₂选择性均未明显降低,表现出较高的活性和化学链循环稳定性。     

N2O在Au/Co3O4和Au/ZnCo2O4催化剂上的分解反应

通过调变HAuCl₄溶液的pH值和Au负载量,用沉积-沉淀法制备了一系列Au/Co₃O₄催化剂,并采用AES、BET、XRD、SEM、XPS和H₂-TPR等技术对催化剂的结构和组成进行了表征,考察了制备条件对其在有氧气氛中催化N₂O分解反应性能的影响规律,得到了催化剂最佳制备条件:HAuCl₄溶液pH值为9,Au负载量为0.29%。催化测试结果表明:虽然ZnCo₂O₄的催化活性优于Co₃O₄,但0.31%Au/ZnCo₂O₄的活性和稳定性低于0.29%Au/Co₃O₄。500℃、在含氧气氛中连续反应10 h, 两者均可完全分解N₂O,但在含氧、含水气氛中0.29%Au/Co₃O₄和0.31%Au/ZnCo₂O₄上的N₂O转化率分别为92%和63%。究其原因,发现Au/Co₃O₄中Au和Co组分间存在协同效应,而Au/ZnCo₂O₄中Au和Co组分间则没有协同效应。     

CF4 decomposition over solid ternary mixture NaF-Si-MO（MO=La2O3,CeO2,Pr6O-（11）,Nd2O3,Y2O3）

A solid ternary mixture consisting of NaF,silicon and one metal oxide such as La2O3,CeO2,Pr6O11,Nd2O3,and Y2O3 was prepared and usedas de-fluorinated reagent for CF4 decomposition.The results show that 90% conversion of CF4 can be reached initially over NaF-Si-La2O3,NaF-Si-CeO2,NaF-Si-Nd2O3,and NaF-Si-Y2O3 at 850 C.The fresh and used reagents were characterized using XRD and XPS techniques.It was found that the active components of NaF and metal oxides in NaF-Si-CeO2,NaF-Si-Pr6O11,NaF-Si-Nd2O3,and NaF-Si-Y2O3 weretransformed into inert phases of mixed metal fluorides and silicates,respectively,resulting in an ineffective utilization of these de-fluorinatedreagents,whereas no inert phases from NaF and La2O3 can be observed in the used NaF-Si-La2O3,indicating the NaF-Si-La2O3 reagent couldbe utilized more efficiently than the other reagents in CF4 decomposition.     

In situ FT-IR study on CO oxidation over Co3O4/CeO2 catalyst

采用沉淀氧化法制备了Co3O4/CeO2催化剂.分别在干、湿条件下进行了一氧化碳氧化反应研究.运用FT-IR表征手段,在钴铈复合氧化物上进行了CO吸附及CO/O2共吸附研究.结果表明,与纯的Co3O4样品相比,Co3O4/CeO2具有明显的抗湿气能力.Co3O4/CeO2催化剂在进行CO氧化时,表面形成了类碳酸盐物种.当环境温度低于453K时,催化剂上类碳酸盐的生成与形成类碳酸盐物种后受热分解存在着动态平衡.当环境温度高于493K,催化剂上生成的类碳酸盐物全部受热分解.氧化铈的加入提高了催化剂的抗湿气性能.较小粒径的Co3O4与CeO2产生的强相互作用可使CeO2向Co3O4提供氧,因而间接提供了CO氧化需要的氧.     

鸡蛋壳负载Co3O4催化剂制备及其N2O分解性能研究

采用废弃的鸡蛋壳作载体,沉积沉淀法制备了一系列不同Co₃O₄含量Co₃O₄/鸡蛋壳催化剂,并在连续流动微反装置上考察了N₂O分解性能。结果表明,当Co₃O₄质量分数为20%时,催化剂表现出优异的N₂O分解性能。在空速10000 h^-1和N₂O含量0.1%的条件下,400℃可实现N₂O完全转化;其比活性约为Co₃O₄催化剂的4.3倍(反应温度为440℃);同时,该催化剂对原料气中3%O₂、3.3%H₂O和/或2.0×10^-4 NO表现出较强的耐受性和较高的稳定性。分析催化剂的多种表征结果发现,CaCO₃作为鸡蛋壳的主要成分,与活性组分Co3O4紧密结合,两者的强相互作用导致20%Co₃O_4...     

MgO/Al2O3吸附剂对CO2动态吸附性能的研究

以γ- Al₂O₃为载体,采用等体积浸渍法制取MgO/Al₂O₃吸附剂,利用BET、XRD等表征手段对吸附剂进行表征;并通过固定床测量穿透曲线的方法研究其对CO2动态吸附性能的影响,考察了MgO负载量、吸附温度、气体流量等因素对吸附剂吸附CO₂性能的影响,同时还通过多次吸脱附实验考察MgO/Al₂O₃吸附剂的稳定性和再生能力。结果表明,MgO负载量为10%的吸附剂,吸附温度在50℃左右,流量为45mL/min动态吸附量最大;经数次循环后材料的结构性质和吸附性能未见明显变化,可再生性能比较优异,是一种潜在的可工业化应用的CO₂吸附剂。     

Ce/Co比对Ag/CeO2-Co3O4催化剂低温氧化降解甲醛性能的影响

采用共沉淀法制备了一系列具有不同Ce/Co比的Ag/CeO₂-Co₃O₄催化剂,对其在甲醛低温氧化降解中的催化性能进行了研究。结果发现,Ag/CeO₂-Co₃O₄催化剂具有较好的甲醛低温降解活性,而Ce/Co比是影响其催化性能的一个重要因素。XRD、氮吸附-脱附、Raman光谱、H₂-TPR和in-situ DRIFTS等表征结果表明,随着Co含量的增加,Ag/CeO₂-Co₃O₄催化剂的孔体积随之增大,而比表面积减小。CeO₂有利于Ag/CeO₂-Co₃O₄催化剂的氧化还原性能提高,促进氧空位增加,提升Co²⁺的含量,从而有利于氧分子的活化,促进甲醛降解。同时,in-situ DRIFTS结果表明,甲酸盐物种的分解是甲醛在Ag/CeO₂-Co₃O₄催化剂表面催化氧化降解的速控步骤。     

固相法制备纳米Co3O4催化剂及其催化甲苯完全氧化性能

采用环境友好的固相法制备了高活性甲苯氧化Co3O4催化剂,通过与传统沉淀法和柠檬酸络合-燃烧法制备的Co3O4催化剂比较,固相合成法制备的Co3O4-SR催化剂在催化甲苯完全氧化反应中表现了很好的活性和稳定性,甲苯转化率为95%时的反应温度T95为230℃,反应60 h活性没有下降.通过XRD,Raman,FT-IR,XPS等手段对Co3O4催化剂的结构和表面性能进行了表征,结果表明固相法制备的Co3O4催化剂具有较多的表面缺陷,催化剂表面Co—O键较弱,具有较强的活化氧的能力,表现出突出的甲苯完全氧化的催化活性.     

Co3O4空心球的简易合成及其电化学性能

通过简易的水热法"一锅"制备了Co3O4空心球。借助X射线衍射仪(XRD)、扫描电子显微镜(SEM)、透射电子显微镜(TEM)和傅里叶变换红外光谱法(FTIR)等对Co3O4的结构和形貌进行了表征。结果表明,产物由Co3O4纳米粒子构成,并形成明显的空心多孔结构。循环伏安法(CV)测试表明,所制得的Co3O4空心球呈现良好的电化学性能。本文同时对Co3O4空心球结构的形成过程和可能的机理进行了分析和讨论。     

Co3O4/KIT-6催化剂催化分解N2O反应研究

本文采用等体积浸渍法将活性组分Co₃O₄负载到具有大比表面积、独特三维交联介孔道的KIT-6分子筛上,制备一种负载型的Co₃O₄/KIT-6催化剂,并用于催化分解N₂O反应.研究发现,负载Co₃O₄后的催化剂不仅保持了KIT-6有序的介孔结构,同时增大了催化剂的有效比表面积,提高了活性组分Co₃O₄的利用率,其催化活性基本与纯Co₃O₄相持平.通过对不同负载量的Co/KIT-6催化剂的活性测试发现,该催化剂的活性随着Co负载量的增加而提升.通过对30%Co/KIT-6催化剂的稳定性测试及其在杂质气体存在条件下的活性测试,表明30%Co/KIT-6催化剂具有较好的催化稳定性和杂质气体抗性,适用于实际工业生产尾气中的N₂O处理.     

Co3O4/CeO2的氧化还原性能及反应条件对其CO氧化活性的影响

采用沉淀氧化法制备了Co₃O₄/CeO₂催化剂。运用XRD、BET和TPR表征手段,考察了不同钴铈比及焙烧温度对钴铈复合氧化物物理及化学性能的影响,并分别在干、湿条件下进行了一氧化碳氧化反应研究。结果表明,与纯的Co₃O₄相比,在不同比例的Co₃O₄/CeO₂均经723 K焙烧的各种催化剂中,钴铈原子比为9∶1的复合氧化物粒径较小,比表面积较大,说明适当比例铈的添加能使Co₃O₄具有较小的粒径。此氧化物经538 K温度焙烧制得的钴铈比为9∶1的复合氧化物中Co₃O₄平均粒径为7.2 nm, BET比表面积为167.6 m²/g。经TPR考察发现其具有最优的氧化还原性能。     

Low-temperature and stable CO oxidation of Co3O4/TiO2 monolithic catalysts

Highly efficient Co₃O₄/TiO₂ monolithic catalysts with enhanced stability were in-situ grown on Ti mesh for CO oxidation,which could completely oxidize CO at 120℃.The comprehensive catalytic performance is competitive to some noble metal catalysts and conventional Co₃O₄ powder catalysts,which holds great potential toward industrial applications.Meanwhile,the in-situ synthesis strategy of Co₃O₄/TiO₂ monolithic catalysts on flexible mesh substrate in this work can be extended to the development of a variety of oxide-based monolithic catalysts towards diverse catalysis applications.     

Effect of Calcination Temperature on Surface Oxygen Vacancies and Catalytic Performance Towards CO Oxidation of Co3O4 Nanoparticles Supported on SiO2

Co₃O₄/SiO₂ catalysts for CO oxidation were prepared by conventional incipient wetness impregnation followed by calcination at various temperatures. Their structures were char-acterized with X-ray diffraction (XRD), laser Raman spectroscopy, X-ray photoelectron spectroscopy (XPS), temperature-programmed reduction (TPR) and X-ray absorption fine structure (XAFS) spectroscopy. Both XRD and Raman spectroscopy only detect the ex-istence of Co₃O₄ crystallites in all catalysts. However, XPS results indicate that excess Co²⁺ ions are present on the surface of Co₃O₄ in Co₃O₄(200)/SiO₂ as compared with bulk Co₃O₄. Meanwhile, TPR results suggest the presence of surface oxygen vacancies on Co₃O₄ in Co₃O₄(200)/SiO₂, and XAFS results demonstrate that Co₃O₄ in Co₃O₄(200)/SiO₂ con-tains excess Co²⁺. Increasing calcination temperature results in oxidation of excess Co²⁺ and the decrease of the concentration of surface oxygen vacancies, consequently the for-mation of stoichiometric Co₃O₄ on supported catalysts. Among all Co₃O₄/SiO₂ catalysts,Co₃O₄(200)/SiO₂ exhibits the best catalytic performance towards CO oxidation, demon-strating that excess Co²⁺ and surface oxygen vacancies can enhance the catalytic activity of Co₃O₄ towards CO oxidation. These results nicely demonstrate the effect of calcination temperature on the structure and catalytic performance towards CO oxidation of silica-supported Co₃O₄ catalysts and highlight the important role of surface oxygen vacancies on Co₃O₄.     

n -Heptane oxidation over co3o4-ceo2 catalyst

The present study reports the catalytic behavior of Co₃O₄-CeO₂ in the oxidation of n-heptane. The results obtained showed that the catalyst give good activity in n-heptane oxidation with high selectivity to carbon dioxide. This revised version was published online in June 2006 with corrections to the Cover Date.     

La2O3助剂对Au/TiO2催化氧化CO性能的影响

采用溶胶-凝胶法制备了TiO2以及La2O3-TiO2载体, 再用沉积沉淀法制备Au/TiO2和Au/La2O3-TiO2催化剂, 并对催化剂的CO氧化反应活性进行测试. 结果表明, La2O3助剂可以显著提高催化剂催化氧化CO的活性. X射线衍射(XRD)、程序升温脱附(TPD)、N2吸附-脱附(BET)表征结果表明, La2O3助剂不仅提高了催化剂比表面积, 抑制了TiO2晶粒尺寸的长大, 并且增强了TiO2的晶格应变, 在O2气氛吸附过程中主要在TiO2表面形成O-物种. 原位傅立叶变换红外(FT-IR)结果进一步表明, La的掺杂不仅提高了吸附在Au活性位CO的氧化速率, 还使TiO2表面形成第二种活性位, 从而显著提高了催化活性.     

Catalytic decomposition of H2O2 on Co3O4 doped with MgO and V2O5

The effects of doping of Co₃O₄with MgO (0.4–6 mol%) and V₂O₅ (0.20–0.75 mol%) on its surface and catalytic properties were investigated using nitrogen adsorption at −196°C and decomposition of H₂O₂ at 30–50°C. Pure and doped samples were prepared by thermal decomposition in air at 500–900°C, of pure basic cobalt carbonate and basic carbonate treated with different proportions of magnesium nitrate and ammonium vanadate. The results revealed that, V₂O₅ doping followed by precalcination at 500–900°C did not much modify the specific surface area of the treated Co₃O₄ solid. Treatment of Co₃O₄ with MgO at 500–900°C resulted in a significant increase in the specific surface area of cobaltic oxide. The catalytic activity in H₂O₂ decomposition, of Co₃O₄ was found to suffer a considerable increase by treatment with MgO. The maximum increase in the catalytic reaction rate constant (k) measured at 40°C on Co₃O₄ due to doping with 3 mol% MgO attained 218, 590 and 275% for the catalysts precalcined at 500, 700 and 900°C, respectively. V₂O₅-doping of Co₃O₄ brought about a significant progressive decrease in its catalytic activity. The maximum decrease in the reaction rate constant measured at 40°C over the 0.75 mol% V₂O₅-doped Co₃O₄ solid attained 68 and 93% for the catalyst samples precalcined at 500 and 900°C, respectively. The doping process did not modify the activation energy of the catalyzed reaction but much modified the concentration of catalytically active constituents without changing their energetic nature. MgO-doping increased the concentration of CO³⁺–CO²⁺ ion pairs and created Mg²⁺–CO³⁺ ion pairs increasing thus the number of active constituents involved in the catalytic decomposition of H₂O₂. V₂O₅-doping exerted an opposite effect via decreasing the number of CO³⁺–CO²⁺ ion pairs besides the possible formation of cobalt vanadate.     

还原-氧化预处理对Co_3O_4催化分解N_2O性能的影响

采用液相沉淀法制备了Co_3O_4催化剂,并对其进行还原-氧化预处理制得Co_3O_4-RO。通过XRD、N_2-physisorption、Raman、H_2-TPR、XPS和O_2-TPD等技术对催化剂进行表征,在连续流动微反应装置上考察了催化剂催化分解N_2O性能。结果表明,经过还原-氧化预处理,与Co_3O_4催化剂相比,Co_3O_4-RO结晶度变差,晶粒粒径减小,尤其是尖晶石结构重构过程削弱了Co-O键,增强了催化剂表面的氧物种脱附能力,降低了催化分解N_2O反应的活化能,因而显著提高了催化剂的催化活性。同时,Co_3O_4-RO对原料气中的O_22%(体积分数)和H_2O 2. 3%(体积分数)表现出较强的耐受性。     

Study on Au/Al2O3 catalysts for low-temperature CO oxidation in situ FT-IR

Au/Al2O3 catalyst was prepared by a modified anion impregnation method and investigated with respect to its initial activity and stability for low-temperature CO oxidation. The activity changes of the catalyst were examined after separate treatment in CO+O2 or CO2+O2. Furthermore, in situ FT-IR studies were performed to investigate the species on the surface when CO or CO+O2 or CO2+O2 was selected separately as adsorption gas. The results showed that Au/Al2O3 catalyst exhibited very high initial activity, but the catalytic activity was found to decrease gradually during CO oxidation with time on stream. And also, the activity of the catalyst declined after treatment in CO+O2 or CO2+O2. The formation and accumulation of carbonate-like species during CO oxidation or treatment in CO+O2 or CO2+O2 might be mainly responsible for the activity decrease, which was reversible.     

CO oxidation over Au/Al2O3catalysts modified by MgO

Summary Au/Al₂O₃catalysts modified by MgO were tested in CO oxidation using temperature programmed technique. Contrary to Au/Al₂O₃the modified Au/MgO-Al₂O₃catalysts showed high activity in the sub-ambient and ambient temperature ranges.