Coadsorption of gold with chlorine on CeO_2(111) surfaces:A first principles study

To investigate the effects of chlorine on the Au/ceria catalysts,the adsorption of gold or chlorine and their coadsorpiton on the stoichiometric and partially reduced CeO2（111） surfaces are studied from the first principles.It is found that the adsorption of Au is significantly enhanced by the chlorine preadsorption on the stoichiometric CeO2（111） surface;while on the partially reduced CeO2（111） surface,the preadsorbed chlorine inhabits the oxygen vacancy（which is the preferred adsorption site for gold）,leading to a CeOCl phase and the dramatical weakening of the Au adsorption.Therefore,chlorine on the CeO2（111） surface can affect the Au adsorption thus the activity of the Au/CeO2 catalyst.

Role of Surface Adsorption in Fast Oxygen Storage/Release of CeO_2-ZrO_2 Mixed Oxides

Four kinds of CeO2-ZrO2 mixed oxides, i.e., a physical mixture of ceria and zirconia （CZP）, zirconia-coated ceria （ZCC）, ceria-coated zirconia （CCZ） and a chemical mixture of celia and zirconia （CZC）, were prepared. The oxygen storage capacity （OSC） measurements at 500℃ were performed under transient and stationary reaction conditions. All the curves of CO2 evolution during CO-O2 cycles presented a bimodal shape. The fast peak was primarily the result of the reaction of CO with the oxygen from the oxides, which was mainly determined by the nature of the material The sec- ond peak was mostly related to the CO2 adsorption behavior and was highly influenced by the surface area and the number of surface active sites. As a result, OSC activity of the samples followed in the order of CZC 〉 CCZ 〉 ZCC=CZP.

CO在CeO_2(111)表面的吸附与氧化

采用密度泛函理论计算了CO在CeO2(111)表面的吸附与氧化反应行为.结果表明,O2在洁净的CeO2(111)表面为弱物理吸附,而在氧空位表面是强化学吸附,且O2分子活化程度较大,O—O键长为0.143nm.CO在CeO2(111)表面吸附行为的研究表明,CO在洁净表面及氧空位表面上为物理吸附,吸附能均小于0.42eV;当表面氧空位吸附O2后,CO可吸附生成二齿碳酸盐中间体或直接生成CO2,与原位红外光谱结果相一致.表面碳酸盐物种脱附生成CO2的能垒仅为0.28eV.计算结果表明,当CeO2表面存在氧空位时,Hubbard参数U对CO吸附能有一定的影响.CeO2载体在氧化反应中可能的催化作用为,在氧气氛下,CeO2表面氧空位吸附O2分子,形成活性氧物种,参与CO催化氧化反应.

Cu_x(x=1-4)团簇在CeO_2(111)表面的吸附(英文)

用基于密度泛函理论的第一性原理方法研究了Cu团簇(Cux,x=1-4)在CeO2(111)表面的吸附.研究发现当团簇比较小时(x=2,3),倾向于平铺表面;当x=4时,Cu团簇在CeO2(111)表面以三维的四面体结构吸附较为稳定,从Cu 3d到Ce 4f的电荷转移使Cu团簇带正电荷.由二维的菱形结构到三维的四面体结构的转变势垒为1.05 eV,并且其中一个Cu原子直接迁移到另外三个Cu原子的空位顶部的转变路径比较有利.在Cu团簇与CeO2的相互作用过程中,Cu-O和Cu-Cu相互作用的竞争最终决定了Cu团簇在CeO2上的形貌.这种CeO2(111)负载的带正电的三维Cu团簇将对水分解,进而对水煤气反应具有高的催化活性.

用密度泛函理论研究汞在CeO_2(111)表面的吸附

采用密度泛函理论计算了Hg、HgCl、HgCl_2在CeO_2(111)表面的吸附构型、吸附能和态密度。结果表明,Hg在CeO_2(111)表面属于弱化学吸附。HgCl与CeO_2(111)表面为强化学吸附,是反应的重要中间体。HgCl_2在CeO_2(111)表面是物理吸附,易发生解离,脱除。氯对于汞的吸附和氧化产生较强的影响,这与实验结果相一致。基于计算结果,得到汞在CeO_2(111)表面的反应机理。

单原子Ge助剂修饰Cu(111)晶面上CO_(2)加氢制甲醇的机理研究

针对CO_(2)热催化转化制甲醇过程中CO_(2)吸附、活化较困难及副产物较多的问题,提出采用单原子Ge助剂修饰Cu(111)晶面的解决思路,通过密度泛函理论(DFT)计算研究了CO_(2)在Ge-Cu(111)晶面上加氢合成甲醇的反应机理。结果表明,单原子Ge助剂的电子调控增加了与其相邻的Cu原子的电子云密度,使CO_(2)分子在含Ge活性界面上的吸附能力显著增强:CO_(2)在GeCu(111)晶面上的吸附能约为Cu(111)晶面的1.5倍,约为Pd改性Cu(111)晶面的2.4倍,进而使逆水煤气变换(RWGS)反应路径速控步骤的活化能降低了近20 kJ·moL^(-1),同时衍生出3条生成甲醇的RWGS新路径;此外,Ge-Cu(111)晶面上甲酸盐路径由于速控步骤活化能大幅上升而被禁阻,进而CO及烃类等副产物选择性大幅降低,Ge-Cu(111)晶面上CO_(2)加氢制甲醇选择性升高。

CeO_2(111)和CeO_2(100)的界面调控合成及在Pt(111)上的结构转变（英文）

氧化铈基催化材料在催化反应中存在显著的晶面效应,为了在分子尺度上理解其催化化学,需要可控合成具有明确表面结构的氧化铈.因此,我们研究了Pt(111)上氧化铈纳米结构和薄膜的生长.人们通常使用金属-氧化物之间的强相互作用来解释Pt/CeO_x催化剂上的催化过程,然而对于Pt与CeO_x之间的强相互作用仍旧缺乏原子尺度上的了解.我们的结果表明, Pt与氧化铈之间的相互作用可以影响氧化铈的表界面结构,这可能会进而影响Pt/CeO_x催化剂的性质.在Pt(111)上生长的氧化铈薄膜通常暴露CeO_2(111)表面.我们发现Pt(111)表面厚度在三层以内的氧化铈薄膜,其结构是高度动态且随着退火温度升高而变化的,这种动态结构变化可归因于Pt和氧化铈间的界面电子作用.当氧化铈薄膜的厚度增大到三层以上,其负载的氧化铈团簇开始表现出迥异于三层以下氧化铈纳米岛的优异的热稳定性,表明Pt与CeO_x之间的界面电子作用主要影响厚度在三层以内的氧化铈纳米结构.采用常规的反应沉积方法难以获得完全覆盖Pt(111)衬底的规整氧化铈薄膜,而我们通过采取一种两步的动力学限制生长方法,制备出了完全覆盖Pt(111)衬底的氧化铈薄膜.对于Pt(111)上厚度约为3-4层的氧化铈薄膜,在超高真空中于1000 K退火会导致氧化铈薄膜表面形成CeO_2(100)结构.这是因为高温还原促进了c-Ce_2O_3(100)缓冲层的形成,该缓冲层被Pt的界面电子转移以及相匹配的超晶格所稳定,并进一步成为顶层CeO_2(100)结构生长的模板.进一步在900 K的氧气中处理则可将薄膜CeO_2(100)表面完全转变为CeO_2(111)表面.因此, Pt(111)上氧化铈纳米岛和薄膜所展现的结构动态变化是由Pt-CeO_x界面作用与氧化铈层间作用相互竞争所决定.本研究提供了对氧化铈负载Pt催化剂的原子级理解,虽然Pt/CeO_2催化剂活性增强的原因常被简单归结于界面强相互作用,我们的研究在原子尺度上进一步表明Pt/CeO_2在还原条件下易形成界面Ce_2O_3层.此外,本研究提供了不同晶面二氧化铈模型催化剂的构筑方法,可将对氧化铈晶面效应和Pt/CeO_x催化剂的研究推进到分子尺度.

CeO2/Pt(111)反向催化剂结构和活性的密度泛函理论研究

铈基材料因其独特的Ce^4+/Ce^3+转化性质而广泛运用于非均相催化反应中.尽管在实验和理论上对纯净二氧化铈表面的物理和/或化学性质进行了深入研究,但是与二氧化铈有关的界面结构和反应性能引起了人们的极大兴趣.其中,已有报道表明,氧化铈/金属反向催化剂相较于氧化铈、金属或者金属/氧化铈负载材料能明显提高CO催化氧化和水汽转化等反应活性.然而多数前期研究并没有从理论上给出合理解释,同时也并未说明反向催化剂中氧化铈结构(层数)和性质的关系.可以预见,因受到金属基板的影响,二氧化铈表面的物化性质,如氧空位形成能、电子分布、催化活性等必然会发生变化.本文通过库伦作用校正的密度泛函理论(DFT+U)计算,系统地研究了不同厚度的Ce O2/Pt(111)反向催化剂几何结构和电子性质,催化CO氧化的性能.本文首先在Pt(111)载体上明确了单层Ce O2(111)的最佳结构,然后研究随着二氧化铈厚度增加,各复合结构界面热力学稳定性、几何结构和电荷性质的变化.计算结果表明:首先,单层Ce O2/Pt(111)比双层和三层Ce O2/Pt(111)复合结构在界面处表现出更强的相互作用,并且其强度与界面结合结构密切相关,如界面O–Pt键的数量及其长度等;其次,氧化铈板层和Pt基板之间的接触会显著影响界面处一个氧化铈层和两个金属层内的电子分布,使氧化铈外暴露表面的氧空位形成能降低~0.3 e V,而界面氧空位形成能则显著降低1.3-1.8 e V,并且当表面上沉积≥2个氧化铈层时,氧化铈/铂复合材料的物理性能会趋向收敛;最后,通过计算单层Ce O2/Pt(111),单层Ce O2和模拟体相结构的三层Ce O2(111)表面上的CO氧化过程,结果表明三者均遵循Mvk机理,并且关键步骤OC…Os偶联的反应能垒分别是0.45,0.33和0.61 e V,表明三者的活性趋势为ML Ce O2>ML Ce O2/Pt(111)>TL Ce O2(111).综合考虑到单层Ce O2/Pt(111)界面处适度的二氧化铈-铂相互作用,一方面可以极大提高复合材料热力学稳定性,另一方面还成功保留了单层二氧化铈的优异催化活性,因此单层Ce O2/Pt(111)复合材料从理论上认为是一种优异的CO氧化催化剂.

硬脂酸对CeO_2纳米粒子的表面修饰研究

利用表面修饰法合成了硬脂酸修饰的 CeO2 纳米粒子,采用透射电子显微镜(TEM)观察了经表面修饰的CeO2 纳米粒子的形貌及分散性,并采用红外光谱(IR)、紫外可见分光光度计等对修饰的CeO2 纳米粒子进行了表征。结果表明:表面修饰剂硬脂酸与 CeO2 纳米粒子表面之间发生了化学键合作用;修饰后的CeO2 纳米粒子表面存在疏水有机基团,阻隔了 CeO2 纳米粒子的团聚,起到了分散作用;同时,修饰后的CeO2 纳米粒子在苯乙烯中的稳定性得到了提高。并且获得了硬脂酸的修饰量与CeO2 纳米粒子的最佳配比。

CeO_2纳米薄膜的光声光谱研究

本文以Ｃｅ（ＮＯ３）３·６Ｈ２Ｏ为前驱物，火棉胶为添加剂，用ｓｏｌ－ｇｅｌ提拉法制备ＣｅＯ２透明薄膜。本方法成膜均匀，重复性好。薄膜的结晶性质和光谱性质研究表明，薄膜中ＣｅＯ２为纳米粒径，具有强烈的量子尺寸效应和表面效应。

Cu(111)面上糠醇加氢生成2-甲基呋喃的反应机理

采用广义梯度近似的密度泛函理论并结合平板模型的方法,详细研究了糠醇在Cu(111)面上反应生成2-甲基呋喃的反应历程,优化了糠醇在Cu(111)面的吸附模型,并采用完全线性同步和二次同步变换的方法,对三种可能的反应机理中的各反应步骤进行了过渡态搜索.结果表明,糠醇主要通过支链上OH与Cu(111)面相互作用,易形成ψCH2和ψCH2O中间体(ψ代表呋喃环).糠醇进一步加氢机理很可能为:引入的氢物种明显降低了糠醇分解形成的中间体ψCH2的活化能,并促进了它的形成;中间体ψCH2更易从糠醇中获得H而生成2-甲基呋喃.该过程的控速步骤为ψCH2O*→ψCHO*+H*,活化能为199.0kJ/mol,总反应是2ψCH2OH=ψCH3+ψCHO+H2O.

表面掺杂CeO_2对2Y-TZP陶瓷抗低温水热腐蚀的影响

比较了对２Ｙ－ＴＺＰ陶瓷采用表面掺杂ＣｅＯ２和体掺杂ＣｅＯ２两种不同方式处理后，２Ｙ－ＴＺＰ陶瓷低温水热腐蚀前后的抗弯强度的变化。结果表明，对Ｙ－ＴＺＰ陶瓷进行表面掺杂ＣｅＯ２，不仅可以克服体掺杂ＣｅＯ２时抗弯强度大幅度下降的问题，而且可以明显改善低温水热腐蚀对Ｙ－ＴＺＰ陶瓷力学性能的影响。表面掺杂ＣｅＯ２对２Ｙ－ＴＺＰ陶瓷抗低温水热腐蚀的原因，是既保持了Ｙ－ＴＺＰ陶瓷整体对等温相变的约束，又阻止了Ｙ－ＴＺＰ陶瓷产生氧空位的综合作用。

Characterization and catalytic performance of CeO_2-Co/SiO_2 catalyst for Fischer-Tropsch synthesis using nitrogen-diluted synthesis gas over a laboratory scale fixed-bed reactor

The surface species of CO hydrogenation on CeO2-Co/SiO2 catalyst were investigated using the techniques of temperature programmed reaction and transient response method. The results indicated that the formation of H2O and CO2 was the competitive reaction for the surface oxygen species, CH4 was produced via the hydrogenation of carbon species step by step, and C2 products were formed by the polymerization of surface-active carbon species （-CH2-）. Hydrogen assisted the dissociation of CO. The hydrogenation of surface carbon species was the rate-limiting step in the hydrogenation of CO over CeO2-Co/SiO2 catalyst. The investigation of total pressure, gas hourly space velocity （GHSV）, and product distribution using nitrogen-rich synthesis gas as feedstock over a laboratory scale fixed-bed reactor indicated that total pressure and GHSV had a significant effect on the catalytic performance of CeO2-Co/SiO2 catalyst. The removal of heat and control of the reaction temperature were extremely critical steps, which required lower GHSV and appropriate CO conversion to avoid the deactivation of the catalyst. The feedstock of nitrogen-rich synthesis gas was favorable to increase the conversion of CO, but there was a shift of product distribution toward the light hydrocarbon. The nitrogen-rich synthesis gas was feasible for F-T synthesis for the utilization of remote natural gas.

NO在Ir(111)表面吸附与解离的第一性原理研究

本文系统研究了NO在Ir(111)表面的吸附,解离,以及可能的N_2生成机理.结果表明,顶位吸附的NO,其解离能垒较高(3.17 eV),不会发生解离,而三重Hcp和Fcc空位吸附的NO发生解离,能垒分别为1.23和1.28 eV.N_2是唯一的生成物,不会有副产物N_2O的产生.其最可能的反应路径为N和NO经过N_2O中间体而生成N_2,而不是直接N提取和N-N聚合产生N_2的机理.

Experimental design for optimization of 4-nitrophenol reduction by green synthesized CeO2/g-C3N4/Ag catalyst using response surface methodology

In this study,the enhancement of catalytic activity of ceria when modified with co-catalysts such as graphitic carbon nitride and silver was establishe d.The material was synthe sized using phytogenic combustion method,a green alternative to the traditional preparative routes.The catalyst was characterized using XRD,FTIR,SEM,EDX,XPS and TEM techniques.The synergistic effect of the composite CeO2/g-C3 N4/Ag was tested for catalytic reduction of 4-nitrophenol in the prese nce of sodium borohydride.The reaction was carried out at room tempe rature without any light source or exte rnal stirring.The individual and combined effects of four parameters,viz.,concentration of 4-NP,amount of catalyst,amount of NaBH4 and time for the reduction of reduction 4-NP were investigated using Box-Behnken design of response surface methodology(RSM).This statistical model was used to optimize the reaction conditions for maximum reduction of 4-NP.The optimum conditions for the reduction reaction are found to be 0.01 mmol/L 4-NP,15 mg catalyst,20 mg NaBH4 and 13.7 min time interval.

Relationships between the activities and Ce^(3+)concentrations of CeO_(2)(111)for CO oxidation:A first-principle investigation

CO oxidation at ceria surfaces has been studied for decades,and many efforts have been devoted to understanding the effect of surface reduction on the catalytic activity.In this work,we theoretically studied the CO oxidation on the clean and reduced CeO_(2)(111)surfaces using different surface cells to dete rmine the relationships between the reduction degrees and calculated reaction energetics.It is found that the calculated barrier for the direct reaction between CO and surface lattice O drastically decreases with the increase of surface reduction degree.From electronic analysis,we found that the surface reduction can lead to the occurrence of localized electrons at the surface Ce,which affects the charge distribution at surface O.As the result,the surface O becomes more negatively charged and therefore more active in reacting with CO.This work then suggests that the localized 4 f electron reservoir of Ce can act as the"pseudo-anion"at reduced CeO_(2) surfaces to activate surface lattice O for catalytic oxidative reactions.

Introduction manner of sulfate acid for improving the performance of SO_4^(2–)/CeO_2 on selective catalytic reduction of NO by NH_3

A series of sulfated CeO2 catalysts were synthesized by impregnation and sol-gel methods and used for selective catalytic reduction （SCR） of NOx by NH3. The results showed that the sulfated CeO2 catalysts prepared by sol-gel method showed excellent catalytic activity at 150-50 ℃, and more than 90% NOx conversion was obtained at 232-450 ℃ with a gas hourly space velocity of 60000 h-1. The catalysts were characterized by X-ray diffraction （XRD）, N2 adsorption, Raman, thermogravimetry （TG）, H2-tem- perature-programmed reduction （H2-TPR） and Py-infrared spectroscopy （Py-IR）. The excellent SCR performance was associated with the surface acidity and the micro-structure. The introduction of sulfate acid into CeO2 could increase the amount of BrOnsted and Lewis acid sites over the catalysts, resulting in the improvement of the low temperature activity. The sulfated CeO2 catalysts prepared by sol-gel method possessed lower crystallization degree, excellent redox property and larger specific surface areas, which were responsible for the superior SCR performance.

Thickness modulation effect of CeO_2 layer for YBCO films grown by pulsed laser deposition

CeO2 film plays an essential role in nucleation and growth of YBa2 Cu3 O（7-x）（YBCO） films. In this work,the dependence of superconducting properties of YBCO on CeO2 films with different thicknesses was investigated,in order to achieve fabrication of high-performance YBCO coated conductors in industrial scale. The crystalline structure and morphology of CeO2 films with thickness ranging from 21 to 563 nm were systematically characterized by means of X-ray diffraction（XRD）, atomic force microscope（AFM） and reflection high-energy electron diffraction（RHEED）. Additional focus was addressed on evolution of the surface quality of CeO2 films with thickness increasing. The results show that at the optimal thickness of 221 nm, CeO2 film exhibits sharp in-plane and out-of-plane texture with full width of half maximum（FWHM） values of 5.9° and 1.8°, respectively, and smooth surface with a mean root-mean-square（RMS） roughness value as low as 0.6 nm. Combing RHEED and transmission electron microscope（TEM） cross-sectional analysis, it is found that nucleation and growth of CeO2 films at early stage remain in island growth mode with rougher surface,while further increasing the thickness beyond the optimal thickness leads to weak surface quality, consequently resulting in degradation of superconductor layers deposited subsequently. Eventually, a critical current density（Jc） as high as 4.6×10-6 A·cm-（-2）（77 K, self-field） is achieved on a YBCO film on a thickness-modulated CeO2/MgO/Y2 O3/Al2 O3/C276 architecture, demonstrating the advantages of CeO2 films as buffer layer in high-throughput manufacture of coated conductors.

分子模拟O_(2)在Ag表面的吸附行为

空气中的Ag熔化时会溶解大量的O_(2),O_(2)在Ag上的吸附特性对研究其相互作用至关重要。基于分子动力学和蒙特卡洛模拟方法,先根据吸附曲线得到了不同温度、压强下O_(2)在Ag(111)表面上的吸附量,然后建立Ag-O_(2)体系的吸附模型,研究了Ag(111)表面对O_(2)的吸附行为。结果表明,O_(2)会大量吸附在Ag表面,距Ag原子0.325 nm处O_(2)最容易被吸附,但随着温度升高,O_(2)在Ag(111)面上的自由能增加、扩散系数增大且吸附能降低。随着压强增大,O_(2)的吸附量逐渐上升,直至达到饱和吸附。

过渡金属掺杂铈中晶格氧的活化

采用密度泛函理论计算研究了在铈表面掺杂的过渡金属(TM)离子对表面晶格氧原子活化的影响.为此,测定了经TM离子修饰的CeO2最稳定(111)表面终端的结构和稳定性.除了保持八面体氧配位的锆和铂掺杂剂外, TM掺杂剂在取代表面Ce离子时更倾向于正方形平面配位.除了Pt(1.14 eV)和Zr(正方形平面配位不稳定)外,所有TM掺杂剂的表面结构从八面体到正方形平面都很容易.通常,四价TM阳离子的离子半径比Ce^4+的小得多,从而导致了显著的拉伸应变晶格,并解释了氧空位形成能量的降低.除Zr外,当产生一个氧空位时,优先形成正方形平面结构.热力学分析表明, TM掺杂CeO2表面在典型环境催化条件下存在氧缺陷.一个具有实际意义的例子是锆掺杂CeO2(111)中的晶格氧容易活化,从而有利于CO氧化.研究结果强调了晶格氧活化的本质和TM掺杂剂在TM-铈固溶催化剂中的优选位置.