甲醇在FeS2(100)完整表面的吸附和分解

采用基于第一性原理的密度泛函理论结合周期平板模型方法, 研究了甲醇分子在FeS₂(100)完整表面的吸附与解离. 通过比较不同吸附位置的吸附能和构型参数发现: 表面Fe位为有利吸附位, 甲醇分子通过氧原子吸附在表面Fe位, 吸附后甲醇分子中的C―O键和O―H键都有伸长, 振动频率发生红移; 甲醇分子易于解离成甲氧基CH3O和H, 表面Fe位仍然是二者有利吸附位. 通过计算得出甲醇在FeS₂(100)表面解离吸附的可能机理: 甲醇分子首先发生O―H键的断裂, 生成甲氧基中间体, 继而甲氧基C―H键断裂, 得到最后产物HCHO和H₂.     

H2分子在LaFeO3表面吸附的第一性原理研究

基于密度泛函理论的第一性原理方法,通过计算表面能确定La Fe O_3(010)表面为最稳定的吸附表面,研究了H_2分子在La Fe O_3(010)表面的吸附性质。La Fe O_3(010)表面存在La O和Fe O_2两种终止表面,但吸附主要发生在Fe O_2终止表面,由于La Fe O_3(010)表面弛豫的影响,使得凹凸不平的表面层增加了表面原子与H原子的接触面积,表面晶胞的纵向体积增加约2.5%,有利于H原子向晶体内扩散。研究发现,H_2分子在La Fe O_3(010)表面主要存在3种化学吸附方式:第一种吸附发生在O-O桥位,2个H原子分别吸附在2个O原子上,形成2个-OH基,这是最佳吸附位置,此时H原子与表面O原子的作用主要是H1s与O_2p轨道杂化作用的结果,H-O之间为典型的共价键。H_2分子的解离能垒为1.542 e V,说明表面需要一定的热条件,H_2分子才会发生解离吸附;第二种吸附发生在Fe-O桥位,1个H原子吸附在O原子上形成1个-OH基,另一个H原子吸附在Fe原子上形成金属键;第三种吸附发生在O顶位,2个H原子吸附在同一个O原子上,形成H_2O分子,此时H_2O分子与表面形成物理吸附,H_2O分子逃离表面后容易形成氧空位。此外,H_2分子在La Fe O_3(010)表面还可以发生物理吸附。     

氮原子在铁低指数面上的吸附位和吸附态

应用原子和表面簇合物相互作用的5参数Morse势方法(5-MP)对N-Fe低指数表面体系进行了系统的研究, 并获得了全部临界点特性, 如吸附位、吸附几何、结合能、正则振动频率等. 计算结果表明: 在Fe(100)面, N原子吸附在四重洞位; 在Fe(110)表面, 趋向于吸附在膺式三重位; 而在Fe(111)表面最稳定的吸附位是近似桥位.     

氢原子在Pt及Pt系双金属催化表面吸附的密度泛函理论研究

采用密度泛函理论(dFT)考察了Pt(100)、(110)、(111)三种表面氢原子的吸附行为, 计算了覆盖度为0.25 ML时氢原子在Pt 三种表面和M-Pt(111)双金属(M=Al, Fe, Co, Ni, Cu, Pd)上的最稳定吸附位、表面能以及吸附前后金属表面原子层间弛豫情况. 分析了氢原子在不同双金属表面吸附前后的局域态密度变化以及双金属表面d 带中心偏离费米能级的程度并与氢吸附能进行了关联. 计算结果表明, 在Pt(100), Pt(110)和Pt(111)表面, 氢原子的稳定吸附位分别为桥位、短桥位和fcc 穴位. 三种表面中以Pt(111)的表面能最低, 结构最稳定. 氢原子在不同M-Pt(111)双金属表面上的最稳定吸附位均为fcc 穴位, 其中在Ni-Pt 双金属表面的吸附能最低, Co-Pt 次之. 表明氢原子在Ni-Pt 和Co-Pt 双金属表面的吸附最稳定. 通过对氢原子在M-Pt(111)双金属表面吸附前后的局域态密度变化的分析, 验证了氢原子吸附能计算结果的准确性. 掺杂金属Ni、Co、Fe 的3d-Pt(111)双金属表面在吸附氢原子后发生弛豫, 第一层和第二层金属原子均不同程度地向外膨胀. 此外, 3d金属的掺入使得其对应的M-Pt(111)双金属表面d带中心与Pt 相比更靠近费米能级, 吸附氢原子能力增强, 表明3d-Pt系双金属表面有可能比Pt具有更好的脱氢活性.     

N_2O在Cu/t-ZrO_2(101)表面的吸附与解离

运用广义梯度密度泛函理论结合周期性平板模型方法研究了N2O在完整及负载Cu的四方相ZrO2(101)表面的吸附与解离.结果表明,N2O在完整ZrO2(101)表面的吸附均为物理吸附,Cu在其完整表面的次表层第一氧位为最稳定吸附位,且覆盖度为0.25ML时的吸附最为稳定,吸附能为155.8kJ/mol;N2O分子中O端弱物理吸附于Cu/ZrO2(101)表面,其N端及平行吸附方式得到的稳定吸附能分别为121.6和66.8kJ/mol.频率及电荷布居计算表明,吸附后对称和反对称伸缩振动频率均发生红移,电子由Cu负载底物表面转移给N2O分子.对N2O分子的解离考虑了N端垂直吸附和平行吸附两种解离反应过程,发现平行吸附过程的解离更易发生.     

氢原子在Fe低指数面及高指数面(211)上的吸附和振动

摘要应用原子和表面簇合物相互作用的5参数Morse势方法(5-MP)对H-Fe低指数表面体系及高指数表面体系进行了系统研究, 并获得了吸附位、 吸附几何、 结合能和正则振动频率等全部临界点特性. 理论计算结果表明, 在Fe(100)面, H原子吸附在四重洞位, H-Fe的垂直振动频率为1 009 cm^-1; 在Fe(110)和Fe(211)表面, 趋向于吸附在赝式三重位, H-Fe的垂直振动频率分别为1 054和1 046 cm^-1; 而在Fe(111)表面最稳定的吸附位是近桥位, 频率为1 030 cm^-1.     

单层 FeO 薄膜表面周期性氧缺陷结构的形成

 采用扫描隧道显微镜和 X 射线光电子能谱对含有次表层 Fe 的 Pt 表皮结构 (Pt skin), 即 0.4 ML Fe 的 Pt/Fe/Pt(111) 表面, 在 1.1 × 10?7 kPa 氧气气氛退火过程中的变化进行了研究. 结果表明, 当退火温度为 600 K 时, 氧气在 Pt/Fe/Pt(111) 表面上解离吸附并诱导表面局域结构的重构; 750 K 时次表层 Fe 可以扩散到表面并被氧化; 当升至 850 K 时, 在样品表面形成单层 FeO 结构, 并且 FeO 表面具有周期性的缺陷. 这种缺陷是由于单层 FeO 薄膜的摩尔条纹单胞中 fcc 位上一个或多个氧原子缺失形成的, 其中多原子空位被确定为缺失 6 个氧原子所致. FeO 表面缺陷结构的研究为理解 Fe-Pt 催化剂在氧化气氛中的结构稳定性以及构造表面活性位提供一定的基础.     

一氧化碳分子在Pt/t-ZrO2(101)表面的吸附性质

运用广义梯度密度泛函理论(GGA-PW91)结合周期平板模型方法,研究了CO分子在完整与Pt负载的四方ZrO2(101)表面的吸附行为.结果表明:表面第二层第二氧位和表面第二桥位分别为CO分子和Pt原子在完整ZrO2(101)表面的稳定吸附位,且覆盖度为0.25ML(monolayer)时均为稳定吸附构型,吸附能分别为56.2和352.7kJ·mol-1.CO分子在负载表面的稳定吸附模式为C-end吸附,吸附能为323.8kJ·mol-1.考察了CO分子在负载表面吸附前后的振动频率、态密度和轨道电荷布居分析,并与CO分子和Pt原子在ZrO2表面的结果进行比较.结果表明,C端吸附CO分子键长为0.1161nm,与自由的和吸附在ZrO2表面后的CO相应值(0.1141和0.1136nm)相比伸长.吸附后C―O键伸缩振动频率为2018cm-1,与自由CO分子相比发生红移;吸附后CO带部分正电荷,电子转移以Pt5dCO2π的π反馈机理占主导地位.     

CO诱导的FeO(111)/Ru(0001)负载Au原子吸附位和电荷的改变

采用密度泛函理论研究了CO气氛对FeO(111)/Ru(0001)负载Au原子吸附位、电荷及其稳定性的影响. 首先考察了FeO(111)单层薄膜在Ru(0001)表面上的界面结构. 研究发现,表面莫尔超晶胞内的HCP区域有最小的Fe-O层间距(rumpling),且Fe和O原子均与衬底Ru形成化学键. Au原子在FeO/Ru(0001)上最稳定的吸附在HCP区域的Fe-bridge位. 其中,Au原子诱导两个Fe原子从O原子层的下面翻转到其上面,形成两个Au-Fe键,且Au带负电. 当把体系暴露在CO气氛下后,CO能诱导Au原子从原来最稳定的Fe-bridge位转移到其邻近的O-top位,伴随着Au的电荷从负变到正,形成非常稳定的Au⁺-CO羰基物. 结果表明,反应气氛对负载金属催化剂的化学状态及其稳定性的影响很大; 同时也强调了反应条件下催化剂原位表征的重要性.     

NiO表面磁性对分子吸附的影响的第一性原理研究

过渡金属氧化物广泛应用在当今能源与环境相关的催化领域,理解其表面化学性质以及结构-反应活性之间的关系对于先进催化材料的进一步发展以至理性设计至关重要.3d后过渡系金属(Mn,Fe,Co,Ni)的氧化物以其中金属离子独特的自旋状态和由此产生的铁磁/反铁磁性为典型特征.研究过渡金属氧化物的自旋状态以及磁性对表面化学的影响将使我们更加完整了解这些材料的表面化学.以NiO为代表的后过渡系金属岩盐结构一元氧化物具有反铁磁性,被经常作为反铁磁研究的模型体系.尽管在低温(低于其Neel温度)下NiO体相的完整晶体具有确定的反铁磁序,但是一系列最新研究表明,在条件变化时NiO表面的Ni离子可以产生不同的磁序.以此为背景,本工作以NiO为模型体系,采用DFT+U的第一性原理方法研究了NiO表面磁序对表面的小分子吸附活性的影响,包括表面吸附活性对各磁性相的表面取向以及吸附物种磁性的依赖关系.我们考察了NiO的5种反铁磁相和一种铁磁相,两个晶面NiO(001)和NiO(011),顺磁性分子NO和非顺磁性分子CO.我们发现表面能受磁性的影响较轻微,NiO(001)面上从49到54 meV/?2,NiO(011)面上从162到172 meV/?2.在NiO(001)面上,CO与NO都倾向于在Ni离子的顶位吸附.对于不同的体相磁序与表面取向,CO吸附能的变化范围为-0.33~-0.37 eV,NO吸附能的变化范围为-0.42~-0.46 eV.在NiO(011)表面,两种分子都倾向于吸附在由两个Ni离子构成的桥位.我们发现相对于NiO不同磁性相的体相长程磁序,吸附位点处构成桥位的两个Ni离子的局部磁矩相对取向对于分子的吸附具有更加显著的影响.计算得到NO在局部磁矩相对取向反平行(↑↓)吸附位点处的吸附能为-0.99~-1.05 eV,在局部磁矩相对取向平行(↑↑)吸附位点处吸附会增强,吸附能为-1.21~-1.30 eV.对于CO,尽管计算的吸附能在(↑↓)吸附位点(-0.73~-0.75 eV)与在(↑↑)吸附位点(-0.71~-0.72 eV)非常接近,两种吸附位点处的CO吸附时分子轨道杂化方式以及吸附后CO的局域电子态密度却具有明显不同的特征.本工作突出揭示了分子在过渡金属氧化物表面的多重吸附位点上吸附时吸附位点的局域磁矩相对取向对吸附性能的影响.     

MgO缺陷和不规则表面的能带结构研究

用扩展休克尔紧束缚（ＥＨＴ）晶体轨道方法对ＭｇＯ表面缺陷和不规则结构进行能带计算,并对能带的结构及组成进行了讨论。计算结果表明,各种缺陷及不规则表面的表面状态与完整晶面比较,存在明显差异,前者由于其导带底部能带的变化造成导带和价带间的能隙减小。我们发现,ＭｇＯ缺陷及不规则表面吸附能力与其表面能大小及表面不同位置原子的净电荷数密切相关。缺陷模型的表面能均大于完整晶面,故缺陷有利于表面吸附     

Behavior of collagen films in presence of structure modifiers at solid–liquid interface

Films of soluble collagen extracted from rat‐tail tendon were studied at the solid–solution interface, and the surface energy of the films was evaluated. The films transferred onto solid substrates using the Langmuir–Blodgett film (LB film) technique were characterized using Fourier transform IR attenuated total reflectance spectroscopy and atomic force microscopy. The properties of the protein in contact with different structure modifiers like basic chromium sulfate (BCS) and formaldehyde (HCHO) were analyzed for the effect of various tanning agents on the protein structure. The thermal properties of the films were studied using differential scanning calorimetry. The results show that the film of collagen treated with BCS exhibits an increase in the peak temperature and enthalpy changes compared to the pure collagen as well as the protein with HCHO. These differences are attributed to the changes in the crosslinks arising from both coordinate–covalent and covalent interactions, respectively. The atomic force micrographs showed an increase in order for the collagen film with BCS compared to the HCHO treated analogue. A similar trend is seen in the surface energy parameters of the protein films on solid surfaces on reacting with BCS and HCHO, suggesting a molecular level ordering process in collagen assemblies. © 2004 Wiley Periodicals, Inc. J Polym Sci Part B: Polym Phys 42: 3859–3865, 2004     

碱性水溶液中甲醛在硅电极表面的电化学行为及其对硅化学刻蚀的影响

研究了KOH水溶液中氧化剂甲醛在p-Si和n-Si(100)单晶半导体电极表面的电化学行为及其对硅化学刻蚀表面形貌的影响．实验结果表明，甲醛不仅影响p-和n-型半导体电极在碱性溶液中的阳极氧化峰电流，而且在负电位区能在Si(100)电极上发生还原．在光照条件下，p-Si(100)电极上也观测到了HCHO的电化学还原及光电流倍增效应．甲醛在硅电极表面的电化学还原反应分两步进行，反应终产物为甲醇．此外，HCHO能有效抑制碱性溶液中Si表面“金字塔”型表面粗糙颗粒的形成。     

Long-range molecular organization of an organic monolayer grafted on a mineral substrate.

Structured and functional materials are of the utmost importance for the development of microelectronic technology. We report on a method to obtain a highly ordered organic molecular layer on a mineral substrate. We took advantage of the regular array of reactive sites present at the single-crystal surface of topaz to perform a liquid-phase silanization reaction. The grazing-incidence diffraction technique was used to characterize the bare and covalently coated surfaces. The ordering of the monomolecular organic layer reproduces the perfect single-crystal structure of the cleaved surface over millimeter distances.     

CaF2负载H3PMo12O40表面上激光促进甲烷部分氧化反应性能的研究

甲烷部分氧化反应是目前催化研究领域的一个热点^[1,2],杂多酸以其确定的化学组成、特定的酸性和氧化性以及空间笼形结构而成为在分子水平上进行催化剂设计的良好选择^[3]。Kasztelan等^[4]曾利用SiO2负载的磷钨酸作为催化剂研究了CH4的氧化过程。激光促进表面反应（LSSR）技术已成为一种充满应用前景的光催化合成方法^[5,6]。本文以磷钼酸和CaF2负载磷钼酸为固体材料,TEA CO2激光器为光源,按固体表面键激发模式,考察了CH4部分氧化反应性能。     

The nature of transition-metal-oxide surfaces

The surfaces of the 3d-transition-metal oxides form a rich and important system in which to study the effects of atomic geometry, ligand coordination and d-orbital population on surface electronic structure and chemisorption. This article considers the properties of those surfaces in terms of the types of surface structures that can exist, including steps and point defects, and their relation to the experimental data that is available for well characterized, single-crystal surfaces. The electronic structure of nearly perfect surfaces is very similar to that of the bulk for many of the oxides that have been studied; atoms at step sites also appear to have properties similar to those of atoms on terraces. Point defects are often associated with surfaces 0 vacancies and attendant transfer of electrons to adjacent metal cations. Those cations are poorly screened from each other, and the excess charge is presumably shared between two or more cations having reduced ligand coordination. Point defects are generally more active for chemisorption than are perfect surfaces, however for Ti₂O₃ and V₂O₃, whose cations have 3d¹ and 3d² electronic configurations respectively, the cleaved (047) surface is more active than are surfaces having a high density of defects. The chemisorption behavior of both nearly perfect and defect surfaces of 3d-transition-metal oxides varies widely from one material to another, and it is suggestive to correlate this with cation d-orbital population. However, too few oxides have yet been studied to draw any firm conclusions. Additional theoretical work on perfect surfaces, defects and chemisorption is also necessary in order to gain a more complete understanding of transition-metal-oxide surfaces.     

Effects of Oxygen Vacancy on the Adsorption of Formaldehyde on Rutile TiO2(110) Surface

Oxygen vacancy (O_v) has significant influence on physical and chemical properties of TiO₂ systems,especially on surface catalytic processes.In this work,we investigate the effects of O v on the adsorption of formaldehyde (HCHO) on TiO₂(110) surfaces through firstprinciples calculations.With the existence of O_v,we find the spatial distribution of surface excess charge can change the relative stability of various adsorption configurations.In this case,the bidentate adsorption at five-coordinated Ti (Ti_5c) can be less stable than the monodentate adsorption.And HCHO adsorbed in O_v becomes the most stable structure.These results are in good agreement with experimental observations,which reconcile the long-standing deviation between the theoretical prediction and experimental results.This work brings insights into how the excess charge affects the molecule adsorption on metal oxide surface.     

Gas-phase and On-surface Chemical Reduction of CO2 to HCHO and CO under Dielectric Barrier Discharge

Selective chemical reduction of CO_2(g) (with carrier Ar) in presence of organic compounds, either mixed in the gas-phase or present as a contact surface, under Dielectric Barrier Discharge is presented in this study. Along with gas-phase CO generation, added hydrocarbons (C _n H _2n+x ; n = 6–12; x = 0 or 2) resulted in HCHO production with the maximum H-atom utilization efficiency being ∼15% of the total present. Product CO and HCHO were estimated separately by pre-concentration in specific absorber solutions followed by their discrete colorimetric measurements. On the other hand, in presence of various types of organic surfaces (e.g. wax, plastics and polymers, also acting simultaneously as a dielectric barrier), it was found that while CO could be estimated as above, in the ensuing chemical conversion, product HCHO was retained on these surfaces. On leaching the HCHO into the absorber solution, its production efficiency was estimated to be ∼5% of CO₂.     

Ab initio study on the adsorption and oxidation of HCHO with Ag2 cluster

We present an ab initio study on the adsorption and oxidation of HCHO on the Ag₂ dimer. HCHO is found to weakly adsorb on the neutral Ag₂ cluster and the adsorption energy increases when the Ag₂ cluster is positively charged. The adsorption of HCHO on Ag₂ is promoted by pre-adsorbed OH species while coadsorbed H has no effect. The formation of η²-methylendioxy is inhibited if the Ag₂ cluster is positively and properly charged, which enhance the selectivity of the partial oxidation of methanol. These results provide insight into the reaction mechanism of HCHO on silver surfaces and may guide the design of novel catalysts.     

NO adsorption on the stoichiometric and reduced SnO2(110) surface

The adsorption of NO molecules on the perfect and defective (110) surfaces of SnO₂ was studied with first-principles methods at the density-functional theory level. It was found that NO mainly interacts via the nitrogen atom with the bridging oxygens of the stoichiometric surface while the coordinatively unsaturated surface Sn atoms are less reactive. On the oxygen-deficient surface, NO is preferentially adsorbed at the vacancy positions, with the nitrogen atom close to the former surface oxygen site. Regardless of the adsorption site, the unpaired electron is located mainly on the NO molecule and only partly on surface Sn atoms. The results for the SnO₂ surface are compared to literature results on the isostructural TiO₂ rutile (110) surface. Dedicated to Professor Karl Jug on the occasion of his 65th birthday