Bonding analysis and electronic structure of transition metal-benzoquinoline complexes: A theoretical study

The geometric and electronic structures of a series of hypothetical compounds of the types CpM(C₁₃H₉N) and (CO)₃M(C₁₃H₉N) (M = first row transition metal and C₁₃H₉N = 7,8-benzoquinoline) have been investigated by means of density functional theory (DFT). The benzoquinoline ligand can bind to the metal through η¹-η⁶ coordination modes, adopting structures of types a, b and c, in agreement with the electron count and the nature of the metal. In the investigated species, the most favored closed-shell count is 18-MVE, except for the Ti and V models which prefer the open-shell 16-MVE configuration. This study has shown the difference in the coordination ability of this heteropolycyclic ligand and coordination of the inner C₆ ring is less favored than the outer C₆ and C₅N rings, in agreement with the π-electron density localization.     

Theoretical investigation of the coordination of dibenzazepine to transition-metal complexes: A DFT study

DFT calculations with full geometry optimizations have been carried out on a series of hypothetical compounds of the CpM(C₁₄NH₁₁) and (CO)₃M(C₁₄NH₁₁) (M = transition metal and C₁₄NH₁₁ = dibenzazepine ligand) type. A rationalization of the bonding in hypothetical complexes is provided. Depending on the electron count and the nature of the metal, the dibenzazepine ligand can bind to the metal through the η¹, η², η³, η⁴ , η⁵, η⁶ , or η⁷ coordination mode adopting structures of types a or b. In the investigated species, the most favored closed-shell count is 18-MVE except for the Sc and V models which prefer the 16-MVE configuration.     

Hydrogen and dihydrogen bonding of transition metal hydrides

Intermolecular interactions between a prototypical transition metal hydride WH(CO)₂NO(PH₃)₂ and a small proton donor H₂O have been studied using DFT methodology. The hydride, nitrosyl and carbonyl ligand have been considered as site of protonation. Further, DFT-D calculations in which empirical corrections for the dispersion energy are included, have been carried out. A variety of pure and hybrid density functionals (BP86, PW91, PBE, BLYP, OLYP, B3LYP, B1PW91, PBE0, X3LYP) have been considered, and our calculations indicate the PBE functional and its hybrid variation are well suited for the calculation of transition metal hydride hydrogen and dihydrogen bonding. Dispersive interactions make up for a sizeable portion of the intermolecular interaction, and amount to 20–30% of the bond energy and to 30–40% of the bond enthalpy. An energy decomposition analysis reveals that the H?H bond of transition metal hydrides contains both covalent and electrostatic contributions.     

DFT calculations on the structural stability and infrared spectroscopy of endohedral metallofullerenes

Endohedral metallofullerenes M@C₂₄ (M = Li^0/+, Na^0/+, K^0/+, Be^0/2+, Mg^0/2+ and Ca^0/2+) with different spin configurations have been systematically investigated using the hybrid DFT-B3PW91 functional in conjunction with 6-31G(d) basis sets. Our theoretical studies show that Li@C₂₄, Be@C₂₄, Be²⁺@C₂₄, and Mg²⁺@C₂₄ are energetically favorable. In these endohedral metallofullerenes, only the encapsulated Be and Ca atoms can donate the electrons to the cage. With exception of Be²⁺@C₂₄, the energy gaps of other charged compounds are larger than that of corresponding neutral compounds. We also find that some endohedral metallofullerenes have high energy gaps, but they are unlikely to show high thermodynamic stability. Additionally, the vibrational frequencies and active infrared intensities are also used as evidence to identify these endohedral metallofullerenes.     

Sandwich-type transition metal complexes [(CBO)n]2M with carbon boronyl ligands (CBO)n (n=4–6)

A density functional theory investigation on a series of sandwich-type transition metal complexes [(CBO)_n]₂M (n=4–6; M=transition metals) with carbon boronyls (CBO)_n as effective aromatic ligands has been presented in this work at B3LYP level. The ground-states of these complexes possess staggered D_nd symmetries, while the corresponding eclipsed D_nh structures exist as transition states with slightly higher energies (within 5.8 kJ/mol). Carbon boronyl complexes [(CBO)_n]₂M are confirmed to be much more stable than their boron carbonyl isomers [(BCO)_n]₂M, which, on the other hand, take eclipsed ground-states with D_nh symmetries. The carbon boronyl complexes [(BCO)_n]₂M proposed in this work parallelize the well-known sandwich-type hydrocarbon complexes [C_nH_n]₂M in coordination chemistry with boronyl groups –BO isolobal to –H atoms in corresponding ligands.     

A density functional study of alizarin two of its isomers and its transition metals and rare-earth complexes

Electronic structure of Alizarin, two of its isomers, 11 different transition metal complexes and five rare-earth complexes are studied using density functional theory (DFT). Complexation energies are evaluated and it is found that chelation has a negligible influence on the structure of the anthraquinone backbone; the molecule keeps a planar conformation except for some metals such as Cr, Al, and Zn where the metal atom M and the oxygen atoms are slightly out of the plane by few degrees. The M–O bonds involve p or d metal orbitals depending on whether the d shell is full or empty. The complexation effect leads to a red shift and hence to a colour change of the solutions of the complexes.

The calculated complexation energies are of the same order for metal transition and for rare-earth elements.     

基于一氧化碳、二氧化碳和氧气分子吸附为探针的碳化钼、碳化钨、氮化钼和氮化钨的表面化学性质：密度泛函理论分析

作为具有吸引力的电极材料,过渡金属碳化物与氮化物被应用在许多电化学储能及能量转换领域. 本工作中,通过密度泛函理论计算,以及一氧化碳 （CO）, 二氧化碳（CO₂）和 氧气（O₂）分子的吸附来表征钼和钨的碳化物及氮化物,如碳化钼（Mo₂C）、碳化钨（W₂C）、氮化钼（Mo₂N）和氮化钨（Mo₂C）的表面化学性质. 这些探针分子可为研究钼和钨的碳化物及氮化物表面在酸性/碱性的氧化还原性质提供衡量方法. 计算结果表明,CO₂分子的吸附发生在路易斯碱位,其碱性降低顺序为α-W₂C(001) > α-W₂N(001) > β-Mo₂C(001) > γ-Mo₂N(100). 此外,CO和O₂分子吸附可用于评估上述碳化物及氮化物的还原能力,其还原性减小顺序为β-W₂C(100) > α-Mo₂C(100) > α-W₂N(001) > α-W₂C(001) > β-Mo₂C(001) > γ-Mo₂N(100). 由于还原本性,使得上述这些碳化物和氮化物成为在各种催化反应中有可能取代贵金属的良好候选材料.     

Capture and separation of CO2 on BC3 nanosheets: A DFT study

In order to reduce the greenhouse effect caused by the rapid increase of CO₂ concentration in the atmosphere, it is necessary to develop more efficient, controllable, and highly sensitive adsorbing materials. In this study, the adsorption behavior of CO₂ on BC₃ nanosheets under an external electric field was explored based on density functional theory (DFT). It was found that CO₂ experienced a transition from physisorption to chemisorption in the electric field range of 0.0060-0.0065 a.u.. In addition, the adsorption/desorption of CO₂ is reversible and can be precisely controlled by switching on/off at the electric field of 0.0065 a.u.. The selective adsorption of CO₂/H₂/CH₄ by BC₃ can also be used to realize gas separation and purification under different electric fields. This study highlighted the potential application of BC₃ nanosheets as a high-performance, controllable material for CO₂ capture, regeneration, and separation in an electric field.     

过渡金属表面上水生成经典Horiuti-Polanyi机理与非Horiuti-Polanyi机理选择的总体趋势（英文）

在非均相催化加氢反应中,氢气(H₂)一直被公认为是通过两步基元步骤参加还原反应的,包括第一步的分子解离和之后的反应物与原子氢键合,即所谓的Horiuti-Polanyi(HP)机理.直到我们研究组在Ag或Au催化丙烯醛加氢还原反应理论研究中发现非HP机理加氢路径存在时,新的机理才被提出,并引起广大研究者的浓厚兴趣.考虑到表面羟基(OH)和氧(O)在非均相催化体系中广泛存在,如常见的过渡金属催化的费托合成、甲烷重整、水汽转化及氨氧化等反应,基于第一性原理的密度泛函理论计算方法,我们对OH/O在一系列过渡金属催化作用下还原生成水的微观机理进行了系统全面的探究.研究发现,不同金属对应于不同的催化氢化反应活性,以及不同的催化反应机理.在某些金属上H₂以分子形式进攻反应物种的非HP机理有利,而在其它金属上经典的H₂解离后参与氢化还原反应的HP机理更容易发生.详细分析显示, H₂的解离活性决定了反应机理的种类:在对H₂解离具有催化活性的金属(如Pt、Ni)表面,不论是(211)台阶面还是(...     

The pristine and carbon,silicon or germanium-substituted (10, 0) BN nanotube: A computational DFT study of NMR parameters

The geometrical structure and nuclear magnetic resonance (NMR) parameters of the pristine as well as carbon, silicon and germanium-doped (10, 0) boron-nitride (BN) nanotubes have been studied using a DFT-B3LYP method for the first time. When either a Ge, C or Si atom is substituted for a single B or N in the BN nanotube, the dopant atom extends outward from the surface of the nanotube. Our results show that Ge extends more from the surface than C or Si. It was found that the NMR parameters are significantly changed for those B and N nuclei that bond directly to C, Si or a Ge dopant. The calculations were carried out using the Gaussian 03 software package.     

DFT Study of Alkali Metal Atom Adsorption on Defect-Free MgO(001) Surface

The adsorption of isolated alkali metal atoms (Li, Na, K, Rb, and Cs) on defect-free sur-face of MgO(001) has been systemically investigated with density functional theory using a pseudopotential plane-wave approach. The adsorption energy calculated is about -0.72 eV for the lithium on top of the surface O site and about one third of this value for the other alkali metals. The relatively strong interaction of Li with the surface O can be explained by a more covalent bonding involved, evidenced by results of both the projected density of states and the charge density difference. The bonding mechanism is discussed in detail for all alkali metals.     

Rational design of FLP catalysts for reversible H2 activation: A DFT study of the geometric and electronic effects

The thermodynamics of reversible H₂ activation could be controlled by adjusting substituents of LA group and using different polar solvents, which forges a guide to design potential FLPs catalysts for reversible H₂ activation.     

First-principles study of structural,elastic, electronic and vibrational properties of BiCoO3

We used density functional theory (DFT) to study the structural, elastic, electronic, and lattice dynamical properties of tetragonal BiCoO₃ applying the “norm-conserving” pseudopotentials within the local spin density approximation (LSDA). The calculated equilibrium lattice parameters and atomic displacements are in agreement with the available experimental and theoretical results. Moreover, the structural stability of tetragonal BiCoO₃ were confirmed by the calculated elastic constants. In addition, the elastic properties of polycrystalline aggregates including bulk, shear and Young's moduli, and Poisson's ratio are also determined. The electronic band structure, total and partial density of states (DOS and PDOS) with ferromagnetic spin configuration are obtained. The results show that tetragonal BiCoO₃ has an indirect band gap with both up- and down-spin configurations and its bonding behavior is of covalent nature. We compute Born effective charge (BEC) which is found to be quite anisotropic of Bi, Co and O atoms. The infrared and Raman active phonon mode frequencies at the Г point are found. The phonon dispersion curves exhibit imaginary frequencies which lead from the high-symmetry tetragonal phase to low-symmetry rhombohedral phase in BiCoO₃. The six independent elastic constants, including bulk, shear and Young's moduli, and Poisson's ratio, complete BEC tensor and phonon dispersion relations in tetragonal BiCoO₃ are predicted for the first time. Results of the calculations are compared with the existing experimental and theoretical data.     

DFT法研究分子筛催化trans-2-丁烯的双键异构

利用一个3T簇模型模拟分子筛催化剂的酸性位, 采用密度泛函理论(DFT)的 B3LYP/6-31G(d, p)方法, 研究了分子筛催化1-丁烯双键异构为trans-2-丁烯的反应机理. 对反应各驻点进行了全优化, 经过零点能校正后, 得到了反应的活化能. 研究表明, 反应分三步进行：物理吸附→化学反应→物理脱附. 分子筛的酸性位OH基团首先吸附1-丁烯的双键形成了π配位复合物, 然后按协同反应机理发生双键异构反应, 生成吸附态的trans-2-丁烯, 最后脱附成产物. 计算得到的表观活化能为57.1 kJ•mol^-1, 与实验结果接近.     

CO2二聚体分子弱结合作用的DFT计算

用密度泛函理论(DFT)的Becke 3LYP方法,在不同基集合（6 31G和6 311G系列）下对平行结构（C 2h）和T形结构(C2v)的CO2二聚体进行ab initio计算.通过计算,得到了CO2二聚体C2h和C2v两种构型的结构参数和离解能,并给出了CO2二聚体相对稳定构型C2h的12个正则振动分析图.结果表明,CO2二聚体的离解能为2 kJ•mol－1,CO2分子之间振动频率很小,从而说明CO2二聚体是弱结合分子.     

Structures and electronic states of fluorinated graphene

Functionalized graphenes have been utilized as electronic devices and energy materials. In the present paper, the effects of fluorine-termination of graphene edge on the structures and electronic states of graphene have been investigated by means of density functional theory (DFT) method. It was found that the ionization potential (Ip) and electron affinity of graphene (EA) are blue-shifted by the F-substitution. On the other hand, the excitation energy was red-shifted. The drastic change shows a possibility as electronic devices such as field-effect transistors. The drastic change of electronic states caused by the F-substitution of graphene edge was discussed on the basis of the theoretical results.     

Synthesis, characterization and formation process of transition metal oxide nanotubes using carbon nanofibers as templates

Mono and binary transition metal oxide nanotubes could be synthesized by the immersion of carbon nanofiber templates into metal nitrate solutions and removal of the templates by heat treatment in air. The transition metal oxide nanotubes were composed of nano-crystallites of metal oxides. The functional groups on the carbon nanofiber templates were essential for the coating of these templates: they acted as adsorption sites for the metal nitrates, ensuring a uniform metal oxide coating. During the removal of the carbon nanofiber templates by calcination in air, the metal oxide coatings promoted the combustion reaction between the carbon nanofibers and oxygen.     

Cyclic M(SO2) (M=Zn,Cd) and its Anions: Matrix Infrared Spectra and DFT Calculations

Reaction of laser ablated zinc and cadmium atoms with SO₂ molecules was studied by low temperature matrix isolation infrared spectroscopy. Cyclic M(SO₂) and anion M(SO₂)^- (M=Zn, Cd) were produced in excess argon and neon, which were identified by ³⁴SO₂ and S¹⁸O₂ isotopic substitutions. The observed infrared spectra and molecular structures were confirmed by density functional theoretical calculations. Natural charge distributions indicated significant electron transfer from s orbitals of zinc or cadmium metal atom to SO₂ ligand and cyclic M(SO₂) complexes favored “ion pair” M⁺(SO₂)^- formation, which were trapped in low temperature matrices. In addition Zn-O or Cd-O bond in M(SO₂) exhibited strong polarized covalent character. Reaction of Hg atom with SO₂ was also investigated, but no reaction product was observed, due to the relativistic effect that resulted in the contraction of 6s valence shell and high ionization potential of Hg atom