钙钛矿型氧化物A(Mg、Ca、Sr)TiO_3的结构及其光催化性能研究

钙钛矿型ABO_3复合氧化物具有良好的热稳定性、催化性能、磁性、导电性以及传感等性质~([1-5]).目前钙钛矿结构复合氧化物以其优异的性能已成为光催化领域的研究热点之一~([6-9]).在钙钛矿型ABO_3复合氧化物中,A位金属可以起到稳定结构的作用,而B位金属为活性位.但是,当B位金属相同A位金属不同的一类钙钛矿型氧化物作为催化剂时,影响其光催化活性的主要因素很少见文献报道.     

LaMnyCo1-yO3催化剂中氧状态的XPS研究

钙铁石型稀土复合氧化物因其结构和性能的多样性，作为重要的功能材料（超导体、电极材料、光学材料、催化剂等）受到普遍重视[1]ABO3型稀土复合氧化物热稳定性高·文献[2-4]曾报导了La1－xCexCoO3、La1－xAx－Mno。、Lal。Sr。CoO。催化剂体系A位离子的偏析、价态和氧的非化学计量问题．本文是保持A位离子La不变，B位离子由Mn、Co组成的体系，通过B位离子组合来讨论过渡金属离子的电子组态导致氧状态变化对催化性能的影响．1实验部分（1）试剂：La（NO3h、Mn（NO3h、Co（NO小分析结（2）催化剂制备：按化学计量比混合溶液，用…     

LaFeO_3的光催化性

LaFeO3属钙钛矿(ABO3)型复合氧化物.其结构、磁性和导电性都已有许多报道[1～3],但对其光催化性报道很少.目前普遍采用的光催化剂TiO2具有光、化学稳定性好、无毒、催化活性高、氧化能力强等优点.由于TiO2禁带宽度(Eg)较宽(约为3.2eV),太阳能的利用率低[4].对钙钛矿(ABO3)型复合氧化物的光催化活性的研究发现,禁带宽度与A—O,B—O的电负性差值有关.如,A—O电负性差值较小的PbO(1.6eV)与B—O电负性差值较大的TiO2(2.0eV)合成的PbTiO3的Eg为2.7eV,正好处在1.77～3.09eV之间(可见光波长700～400nm对应光子的能量范围)吸收可见光…     

Lan+1NinO3n+1(n=1～4)复合氧化物的制备、表征和催化性能的研究

合成了(AO)(ABO3)n(A=La, B=Ni, n-1～4)型系列复合氧化物。用XRD, XPS,IR, TPD, TPR等方法对其进行了表征, 研究了结构特征, 氧化-还原性能。用化学分析方法测定了镍的价态及氧缺陷, 考察了该系列复合氧化物对CO, CH4的完全氧化活性, 并对其活性与化学组成及结构间的关系进行了讨论。     

ABO_3钙钛矿型复合氧化物光催化活性与B离子d电子结构的关系

在ABO3钙钛矿型复合氧化物中 ,B离子的d电子结构对B3d-O2p之间的电荷转移能ΔCT及B -O之间的结合能起着关键作用 ,是影响ABO3复合氧化物光催化活性的一个重要因素 .本文以研磨法和柠檬酸法合成了系列LaBO3(B =Ti-Co) ,并结合光催化降解实验和光声光谱图分析得出 :LaBO3光催化活性随B离子 3d电子数的递增而逐渐增加     

LaFeO3的光催化性

LaFeO3属钙钛矿(ABO3)型复合氧化物.其结构、磁性和导电性都已有许多报道[1～3],但对其光催化性报道很少.     

钙钛矿型(La_(0.8)M_(0.2))MnO_3和(La_(0.8)Sr_(0.2))(Mn_(1-x)Fe_x)O_3的XRD和IR光谱的研究

合成了（La0.8M0.2）MnO3（M=Ca2+，Sr2+，Ba2+）和（La0.8Sr0.2）（Mn1-xFex）O3（x=0．1、0．2、0．3、0．4、0．5）两类氧化物，经XRD确认为钙铁矿型氧化物，应用FT－IR对其进行研究，对主要的红外特征振动υ（Mn-O）和δ（O-Mn-O）进行分析表征。这类化合物的υ（Mn-O）和δ（O-Mn-O）的FT－IR特征吸收峰十分相似，但在～608cm－1处出现较大差别，以Sr2+、Ca2+和Ba2+部分A位取代La3+的钙铁矿型氧化物和B位Fe取代Mn时，由于离子的溶解能不同，对晶格的有序排列的影响程度不一，导致了Mn－O键的键力场不同，引起了吸收峰向低波数移动。这种结构上的差异，导致对汽车尾气中的有害成份碳氢化合物（HC）和一氧化碳（CO）的催化氧化能力降低。借此可以用于研究结构与催化性能的关系。     

钙钛矿型复合氧化物光催化研究进展

扼要叙述了钙钛矿型复合氧化物(ABO3)作为光催化剂的研究进展。包括结构,机理,制备,改性和研究现状。强调了结构与性能之间的关系并对其研究方向提出了自己的见解。     

柠檬酸络合法制备La1-xPbxFeO3及其光催化性能

用柠檬酸络合法制备了钙钛矿型复合氧化物LaFeO3,并按不同比例进行掺杂,制备了La1-xPbxFeO3(x=0,0.1,0.3,0.5,0.7)。用XRD,SEM,IR,UV-vis等方法对其进行表征,其结构均为钙钛矿型。并测定了其对活性艳红X-3B水溶性染料脱色的光催化活性。实验结果表明:在A位掺杂Pb2 ,产生了较多氧空位,降低了光生电子与空穴的复合速率,使LaFeO3的光催化活性明显提高,其中La0.7Pb0.3FeO3效果最佳。     

铜钴尖晶石复合氧化物催化剂的组成对二甲苯完全氧化反应催化性能的影响

具有特定结构的复合氧化物,如ABO3,A2BO4及AB2O4等对某些反应比单一氧化物具有更好的催化性能[1,2]. 然而,有关尖晶石型复合氧化物AB2O4对有机物燃烧反应催化性能的研究相对较少,且常用的模型反应大都是一氧化碳或甲烷的催化氧化反应[3]. 超微粒子由于具有大的比表面积和高的表面能等特性,在催化领域已日益引起人们的重视[4]. 低温固相合成是近十几年发展起来的一种新的超细粒子制备方法[5]; 它具有不使用溶剂,无废液排放,工艺过程简单,能耗低等优点,属于对环境友好的“绿色化学”. 目前,此法在合成多组分复合氧化物及催化化学中的应用仍不多见. 本文以含有结晶水的醋酸铜和醋酸钴为原料,采用低温固相合成法制备了单组分氧化铜和氧化钴,以及三种不同铜钴比的铜钴尖晶石型复合氧化物,并以二甲苯氧化为模型反应,采用XRD,BET及程序升温还原(TPR)等手段进行了研究.     

Site-selected doping of upconversion luminescent Er3+ into SrTiO3 for visible-light-driven photocatalytic H2 or O2 evolution

A series of upconversion luminescent erbium-doped SrTiO(3) (ABO(3)-type) photocatalysts with different initial molar ratios of Sr/Ti have been prepared by a facile polymerized complex method. Er(3+) ions, which were gradually transferred from the A to the B site with increasing Sr/Ti, enabled the absorption of visible light and the generation of high-energy excited states populated by upconversion processes. The local internal fields arising from the dipole moments of the distorted BO(6) octahedra promoted energy transfer from the high-energy excited states of Er(3+) with B-site occupancy to the host SrTiO(3) and thus enhanced the band-to-band transition of the host SrTiO(3). Consequently, the erbium-doped SrTiO(3) species with B-site occupancy showed higher photocatalytic activity than those with A-site occupancy for visible-light-driven H(2) or O(2) evolution in the presence of the corresponding sacrificial reagents. The results generally suggest that the introduction of upconversion luminescent agents into host semiconductors is a promising approach to simultaneously harnessing low-energy photons and maintaining redox ability for photocatalytic H(2) and O(2) evolution and that the site occupancy of doped elements in ABO(3)-type perovskite oxides greatly determines the photocatalytic activity.     

Ag/ZnO heterostructure nanocrystals: synthesis, characterization, and photocatalysis

A high yield of the dimer-type heterostructure of Ag/ZnO nanocrystals with different Ag contents is successfully prepared through a simple solvothermal method in the absence of surfactants. The samples are characterized by X-ray diffraction, transmission electron microscopy, X-ray photoelectron spectroscopy, UV-vis spectroscopy, and IR spectroscopy. The results show that all samples are composed of metallic Ag and ZnO; Ag nanoparticles locate on the surface of ZnO nanorods; the binding energy of Ag 3d(5/2) for the Ag/ZnO sample with a Ag content of 5.0 atom % shifts remarkably to the lower binding energy compared with the corresponding value of pure metallic Ag because of the interaction between Ag and ZnO nanocrystals; the concentration of oxygen vacancy for the as-synthesized samples varies with the increasing Ag content, and the Ag/ZnO sample with a Ag content of 5.0 atom % has the largest density of oxygen vacancy. In addition, the relationship between their structure and photocatalytic property is investigated in detail. It is found that the photocatalytic property is closely related to its structure, such as heterostructure, oxygen defect, and crystallinity. The presence of metallic Ag nanoparticles and oxygen vacancy on the surface of ZnO nanorods promotes the separation of photogenerated electron-hole pairs and thus enhances the photocatalytic activity.     

Electron Configuration Modulation of Nickel Single Atoms for Elevated Photocatalytic Hydrogen Evolution

The emerging metal single‐atom catalyst has aroused extensive attention in multiple fields, such as clean energy, environmental protection, and biomedicine. Unfortunately, though it has been shown to be highly active, the origins of the activity of the single‐atom sites remain unrevealed to date owing to the lack of deep insight on electronic level. Now, partially oxidized Ni single‐atom sites were constructed in polymeric carbon nitride (CN), which elevates the photocatalytic performance by over 30‐fold. The 3d orbital of the partially oxidized Ni single‐atom sites is filled with unpaired d‐electrons, which are ready to be excited under irradiation. Such an electron configuration results in elevated light response, conductivity, charge separation, and mobility of the photocatalyst concurrently, thus largely augmenting the photocatalytic performance.     

过渡元素掺杂对纳米TiO_2光催化剂性能的影响

以沉淀法制备得到了第一过渡系23至30号元素(V, Cr, Mn, Fe, Co, Ni, Cu, Zn)分别掺杂的纳米TiO_2光催化剂。考察了它们光催化降角水中十二烷基苯磺酸 钠的活性，研究了它们的光催化活性与催化剂微晶结构、电子亲和势与离子半径比 、离子的磁矩之间的关系。发现其催化活性的变化与这些元素的稳定氧化态的电子 亲和势与离子半径的比值和掺杂原子的磁矩具有较好的相关性。而催化剂的（101 ）晶面的XRD衍射强度、微晶尺寸和晶格畸变应力对催化活性也具有一定的影响。     

具有高光催化活性的黑色TiO2（B）/锐钛矿双晶TiO2-x纳米纤维

高效TiO2基光催化材料的开发一直是催化领域的研究热点,主要的策略是如何有效地分离光生载流子.制备多晶相的TiO2材料可引入异质/相结结构使电子与空穴朝不同方向移动,从而避免电子与空穴复合;另外,在TiO2中掺杂其他金属或非金属也可以有效地降低电子与空穴的复合率,掺杂的元素作为电子捕获阱俘获光生电子,以实现电子空穴的有效分离.近些年,作为一种全新的掺杂剂,氧空穴可以有效改善TiO2的光催化活性,所制TiO2具有可见光的全光谱吸收能力,因此该类TiO2呈现出黑色.通过上述方法均可以制备出高活性TiO2基光催化材料,如果能够将这些方法耦合一起,则可能制备出活性更高的光催化剂.因此,本文将异相结结构和空穴掺杂耦合起来,用多孔钛酸盐衍生物在H2中高温焙烧制得一种全新的黑色TiO2(B)/锐钛矿双晶TiO2–x纳米纤维.不同于其他TiO2基光催化材料,该样品仅由Ti和O元素组成,通过Ti和O元素的组合,形成了双晶结构和空穴掺杂两种特殊的结构,借助场发射(FESEM)、拉曼光谱(Raman)、氮气物理吸脱附、X射线光电子能谱(XPS)、热重(TG)、紫外可见漫反射光谱(UV-Vis)和荧光光谱(PL)等表征分析了样品的结构及其光催化性能间构效关系. FESEM结果显示,黑色TiO2(B)/锐钛矿双晶TiO2–x为长1–5mm、宽0.2mm的纤维结构, Raman结果表明,锐钛矿相在特征波段(140 cm–1左右)和TiO2(B)的特征波段(220–260 cm–1)均发生蓝移,说明该两相中均存在氧空穴;该样表面未检测到Ti3+,因此氧空穴可能分散在TiO2(B)和锐钛矿相的体相中.根据黑色TiO2(B)/锐钛矿双晶TiO2–x和白色TiO2(B)/锐钛矿双晶TiO2的失重差,估算出前者的O/Ti原子比为1.97.光催化降解甲基橙实验结果显示,黑色TiO2(B)/锐钛矿双晶TiO2–x的光催化活性是白色双晶TiO2的4.2倍,锐钛矿TiO2的10.5倍,且连续反应10次后未出现失活现象,显示出了良好的光催化稳定性.前期,我们已经证明了白色TiO2(B)/锐钛矿双晶TiO2由于具有TiO2(B)和锐钛矿的异相结结构,致使其电子空穴有效地分离,从而表现出优异的光催化活性;本文的PL结果显示,由于氧空穴的引入,异相结与氧空穴两者共同作用,进一步促进了黑色TiO2(B)/锐钛矿双晶TiO2–x电子与空穴的有效分离,因此黑色TiO2(B)/锐钛矿双晶TiO2–x表现出高的光催化活性.由于其特殊的结构,黑色TiO2(B)/锐钛矿双晶TiO2–x纳米纤维将在环境与能源领域表现出良好的应用前景.     

Reactions of methyl fluoride with atomic transition-metal and main-group cations: gas-phase room-temperature kinetics and periodicities in reactivity

Reactions of CH(3)F have been surveyed systematically at room temperature with 46 different atomic cations using an inductively coupled plasma/selected-ion flow tube tandem mass spectrometer. Rate coefficients and product distributions were measured for the reactions of fourth-period atomic ions from K(+) to Se(+), of fifth-period atomic ions from Rb(+) to Te(+) (excluding Tc(+)), and of sixth-period atomic ions from Cs(+) to Bi(+). Primary reaction channels were observed corresponding to F atom transfer, CH(3)F addition, HF elimination, and H(2) elimination. The early-transition-metal cations exhibit a much more active chemistry than the late-transition-metal cations, and there are periodic features in the chemical activity and reaction efficiency that maximize with Ti(+), As(+), Y(+), Hf(+), and Pt(+). F atom transfer appears to be thermodynamically controlled, although a periodic variation in efficiency is observed within the early-transition-metal cations which maximizes with Ti(+), Y(+), and Hf(+). Addition of CH(3)F was observed exclusively (>99%) with the late-fourth-period cations from Mn(+) to Ga(+), the fifth-period cations from Ru(+) to Te(+), and the sixth-period cations from Hg(+) to Bi(+) as well as Re(+). Periodic trends are observed in the effective bimolecular rate coefficient for CH(3)F addition, and these are consistent with expected trends in the electrostatic binding energies of the adduct ions and measured trends in the standard free energy of addition. HF elimination is the major reaction channel with As(+), while dehydrogenation dominates the reactions of W(+), Os(+), Ir(+), and Pt(+). Sequential F atom transfer is observed with the early-transition-metal cations, with the number of F atoms transferred increasing across the periodic table from two to four, maximizing at four for the group 5 cations Nb(+)(d(4)) and Ta(+)(d(3)s(1)), and stopping at two with V(+)(d(4)). Sequential CH(3)F addition was observed with many atomic cations and all of the metal mono- and multifluoride cations that were formed.     

CuC、CuN分子基态的结构与分析势能函数

在Cu 的有效核势近似下, 运用密度泛函(B3LYP)方法, 对Cu采用基集合LANL2DZ, 但对其价电子基组的p轨道函数部分做了必要的修改, 而对C、N采用基集合6-311+G(d), 对CuC和CuN分子的微观结构进行了理论计算. 优化并计算了两分子基态的能量, 平衡结构和谐振频率. 根据原子分子反应静力学原理, 导出了CuC和CuN分子基态的合理离解极限和离解能. 应用密度泛函(B3LYP)方法扫描了CuC和CuN分子基态的势能曲线, 并采用最小二乘法拟合了两分子基态的Murrell-Sorbie势能函数及其在平衡位置附近的Dunham展开式. 同时根据Herzberg 和Dunham的公式, 计算了CuC和CuN分子基态的光谱参数.     

LaFe1-xCuxO3光催化降解水溶性染料的活性

采用柠檬酸法合成了钙钛矿型复合氧化物催化剂LaFeO3,并按不同比例进行掺杂,制备了LaFe1-xCuxO3(x=0.01～0.09)系列样品.以高压荧光汞灯为光源,测定了该系列样品对酸性红3B等水溶性染料的光催化降解活性.采用红外、紫外、光声光谱及正电子寿命谱等技术分析了催化剂的光催化性能及掺杂对活性的影响.结果表明,掺杂后LaFeO3的光催化活性明显提高,这主要与B离子的d电子结构有关.     

Topological analysis of the electronic charge density in the ethene protonation reaction catalyzed by acidic zeolite

In the present work, the distribution of the electronic charge density in the ethene protonation reaction by a zeolite acid site is studied within the framework of the density functional theory and the atoms in molecules (AIM) theory. The key electronic effects such as topological distribution of the charge density involved in the reaction are presented and discussed. The results are obtained at B3LYP/6-31G(**) level theory. Attention is focused on topological parameters such as electron density, its Laplacian, kinetic energy density, potential energy density, and electronic energy density at the bond critical points (BCP) in all bonds involved in the interaction zone, in the reactants, pi-complex, transition state, and alkoxy product. In addition, the topological atomic properties are determined on the selected atoms in the course of the reaction (average electron population, N(Omega), atomic net charge, q(Omega), atomic energy, E(Omega), atomic volume, v(Omega), and first moment of the atomic charge distribution, M(Omega)) and their changes are analyzed exhaustively. The topological study clearly shows that the ethene interaction with the acid site of the zeolite cluster, T5-OH, in the ethene adsorbed, is dominated by a strong O-H...pi interaction with some degree of covalence. AIM analysis based on DFT calculation for the transition state (TS) shows that the hydrogen atom from the acid site in the zeolitic fragment is connected to the carbon atom by a covalent bond with some contribution of electrostatic interaction and to the oxygen atom by closed shell interaction with some contribution of covalent character. The C-O bond formed in the alkoxy product can be defined as a weaker shared interaction. Our results show that in the transition state, the dominant interactions are partially electrostatic and partially covalent in nature, in which the covalent contribution increases as the concentration and accumulation of the charge density along the bond path between the nuclei linked increases.