应用有机结构数据库系统研究钼簇合物的键价规律

本文基于有机结构数据库CSD中簇合物的大量信息, 依靠计算机检索、图形显示和运算功能, 系统分析了449个钼簇合物的价电子总数和Mo-Mo键的键价, 键长, 提出钼簇合物的价电子Counting规则和Mo-Mo键的总键价计算修正公式, 总结出Mo-Mo键的键价、健长等。     

若干簇合物的键价和催化反应机理

在“过渡金属簇合物的键价”一文中,我们提出计算簇合物中金属原子间键价的方法。它有助于了解簇合物的几何构型和化学性质,也可进一步了解簇合物的催化性能和催化机     

簇合物Mo2X4(X＝S,O)电子结构和光谱性质的Ab Initio研究

在abinitio水平上对含cis/trans-MO₂S₄核和含Mo₂O₄核簇合物的电子结构进行了研究.对钼原子选取和构造了一组适合于含Mo-Mo金属键的双核钼簇合物从头算的(4s4p2d)基组,利用该基组并结合自然键轨道(NBO)方法,对含上述簇胳的3个簇合物的电子结构进行了研究,并与相应的钨簇合物进行了比较.     

金属簇状化合物化学

簇状化合物(简称簇合物)一般是指含有一个以上金属-金属键(记为 M—M 键)的多核化合物。随着簇合物化学的蓬勃发展,它的研究范围被扩大到金属原子间仅有配体桥联而无明显键联的化合物以及硼烷、碳硼烷及金属杂硼烷等。早在1906年就报道了组成为 Ta_6Cl_(14)·4H_2O     

线形碳元素簇合物的成键性质

在ab initio 3-21G水平上, 用能量梯度法优化了线性碳元素簇合物C_n~e(n为成簇原子个数, e为电荷)的平衡几何结构. 所得的电离势随成簇原子个数的改变, 呈现出不同程度的奇偶交替变化趋势. 在ab initio计算基础上, 用Boys方法, 对其占据正则分子轨道进行定域化变换, 得到了它们的定域分子轨道. 对定域分子轨道性质的分析表明, 线性碳元素簇合物中, 主要键型有双中心σ和π健, 双中心弯键和三中心香蕉健, 以及多中心σ和π健. 这种键型的多样化可视为小元素簇的成健特征. 此外, 通过对其成键性质的分析, 讨论了线性碳元素簇的稳定性. 对于小碳元素簇, 化学键的共轭性对其稳定性具有十分显著的作用.     

簇电荷对金属—金属键影响的量子化学研究

在探讨过渡金属原子簇化合物的金属——金属键的本质时,簇电荷的影响已引起人们的注意。簇电荷对金属——金属键的作用比较复杂,其中有价电子的成键效应和金属原子氧化数变化所产生的电荷效应。键长与簇电荷之间很难找到简单的关系。Cotton等曾对此问题做过初步讨论,但尚缺定量或半定量的理论计算依据,本文采用改进的电荷自洽EHMO程序(MAD—SCCO-EHMO)计算一系列Mo,Tc,Ru,Rh,和Re等二核簇的电子结构,根据M(?)lliken重迭集居分析,讨论簇电荷对金属——金属键的影响。     

小镍团簇Nin(n=2～6)电子结构和拓扑分析

在UBP86/TZVP水平上计算了小镍团簇(Ni<,n>,n=2～6)的稳定基态结构并用自然键轨道(NBO)和分子中的原子量子理论(QTAIM)分析了这些团簇的电子结构.计算结果表明,Ni团簇基态结构具有较高自旋多重度.QTAIM分析表明镍团簇中Ni-Ni键均为金属键.除Ni<,2>团簇中Ni-Ni键为纯粹的σ键外,其...     

(Mo_3S_4)_2M~(8+)(M=Mo,Sn,Cu_2)型夹心簇合物的电子结构研究

经对一系列夹心簇合物(H_2O)_9Mo_3S_4MS_4Mo_3(H_2O)_9~(8+)(M=Mo,Sn,Cu_2)的量子化学计算和分析,发现该簇合物是通过配体Mo_3S_4~(4+)中的多中心d-pπ轨道与中心原子键合成簇,其成簇机理与经典的以有机共轭环为配体的夹心配合物十分相似,研究了夹心簇的构型、磁性及电子光谱等性质的分子轨道本质,揭示了多中心d-pπ键的变化与簇合物性质的内在联系。     

价键理论中的组态相互作用

近 2 0年来 ,从头计算水平的价键 (VB)方法得到了人们的重视 ,并广泛应用于化学反应等问题的研究[1～ 5] ,然而目前价键理论的计算方法仍然很不完善 .用 VBSCF方法进行计算虽然比较简单 ,能正确地描述化学反应的形成机理 ,但数值结果不理想 ;而用 BOVB方法[4 ] 进行计算虽然可以得到较好的计算结果 ,但存在收敛困难等问题 .分子轨道理论中的组态相互作用是一种简单直接的电子相关能计算方法 ,显然这一方法可以应用于价键方法中 .然而与分子轨道理论方法不同 ,在价键方法中 ,无法直接得到空轨道 ,此外如何选取激发价键函数使得计算结果…     

Roussin红盐和Roussin黑盐的电子结构

Roussin黑盐簇阴离子及其"元件化合物"Roussin红盐簇阴离子,是固氮酶活性中心福州模型I(网兜状原子簇模型)的模型物.本文用闭壳层CNDO/2(S,D方案)法计算了它们的电子结构.根据计算所得的Mulliken重叠集居,电荷密度,分子轨道能量和轨道特征等数据,对成键性质进行了分析,得出如下主要结论:两种簇阴离子骨架电子的非定域性都比较强,桥硫原子Sb在由红盐形成黑盐的电子转移过程中起施主作用,两种簇阴离子中都存在M-M键,强度与M-Sb键相近,其主要贡献都来源于金属的s,pz,dz2轨道与硫原子的s,pz轨道之间的σ作用,金属d轨道的π作用对整个骨架的成键贡献很小.     

Building a bridge between coordination compounds and clusters: bonding analysis of the icosahedral molecules [M(ER)12] (M = Cr, Mo, W; E = Zn, Cd, Hg)

The bonding situation of the icosahedral compounds [M(EH)(12)] (M = Cr, Mo, W; E = Zn, Cd, Hg), which are model systems for the isolated species [Mo(ZnCp*)(3)(ZnMe)(9)] possessing the coordination number 12 at the central atom M, have been analyzed with a variety of charge and energy decomposition methods (AIM, EDA-NOCV, WBI, MO). The results give a coherent picture of the electronic structure and the nature of the interatomic interactions. The compounds [M(EH)(12)] are transition metal complexes that possess 12 M-EH radial bond paths (AIM) that can be described as 6 three-center two-electron bonds (MO). The radial M-EH bonds come from the electron sharing interactions mainly between the singly occupied valence s and d AOs of the central atom M and the singly occupied EH valence orbitals (MO, EDA-NOCV). The orbital interactions provide ~42% of the total attraction, while the electrostatic attraction contributes ~58% to the metal-ligand bonding (EDA-NOCV). There is a weak peripheral E-E bonding in [M(EH)(12)] that explains the unusually high coordination number (MO). The peripheral bonding leads for some compounds [M(EH)(12)] to the emergence of E-E bond paths, while in others it does not (AIM). The relative strength of the radial and peripheral bonding in [Al(13)](-) and [Pt@Pb(12)](2-) is clearly different from the situation in [M(EH)(12)], which supports the assignments of the former species as cluster compounds or inclusion compounds (MO, WBI). The bonding situation in [WAu(12)] is similar to that in [M(EH)(12)].     

过渡金属簇合物合成化学

本文以与催化作用紧密相关的金属羰基簇合物的合成和与化学仿生相关的铁硫和钼铁硫簇合物的合成为例,评述了过渡金属簇合物合成化学的发展概况,给出了金属-金属间键合的两条通则(低氧化态金属间容易成键和同一族元素中重金属具有较大的成键倾向)和三类簇合物的主要合成路线。     

Fe-S簇合物的Fe-Fe相互作用及电子结构规律

本文对Fe-S原子簇化合物中的Fe-Fe相互作用作了详细的分子轨道分析。指出硫桥对形成原子簇的重要作用以及对Fe-Fe间成键的影响。在理论分析的基础上提出了Fe平均价态的计算公式。     

Infrared Spectra,Structures and Bonding of Binuclear Transition Metal Carbonyl Cluster Ions

Binuclear transition metal carbonyl clusters serve as the simplest models in understanding metal-metal and ligand bonding that are important organometallic chemistry catalysis. Binuclear first row transition metal carbonyl ions are produced via a pulsed laser vaporization/supersonic expansion cluster ion source in the gas phase. These ions are studied by mass-selected infrared photodissociation spectroscopy in the carbonyl stretching frequency region. Density functional theory calculations have been performed on the geometric structures and vibrational spectra of the carbonyl ions. Their geometric and electronic structures are determined by comparison of the experimental IR spectra with the simulated spectra. The structure and the metal-metal and metal-CO bonding of both saturated and unsaturated homonuclear as well as heteronuclear carbonyl cluster cations and anions are discussed.     

Chemical bonding in refractory transition metal compounds with 8, 9, and 10 valence electrons

The chemical bonding in the refractory transition metal compounds TiC, TiN, and VN is investigated by experimental and theoretical techniques. High-precision X-ray diffraction is used to determine the electron densities in these three compounds experimentally. The X-ray structure factors and the respective valence electron densities are used twice, once to understand the chemical bonding and once to relate the experimental charge densities to those obtained from band structure calculations. These calculations, which in general are in very good agreement with experimental data, utilize the linearized augmented plane wave (LAPW) method. Theory and experiment lead to a detailed analysis of the chemical bonding in these compounds with 8, 9, and 10 valence electrons. By decomposition of the theoretical charge density into contributions from different states (energy regions), it was possible to show the strong covalent nonmetal p-metal d interaction, which is otherwise apparent only in TiC, but not in TiN or VN. In the latter two compounds the additional electrons occupy mainly metal d states with t_2g symmetry, so that in the total valence charge densities the most important bonding feature is covered. In addition to covalent interactions all compounds have a metallic bonding contribution as well as a considerable charge transfer from the metal to the nonmetal site. This mixture in chemical bonding accounts for the unusual combination of properties such as ultrahardness, high melting points, and good conductivity.     

原子簇化合物的键价分析

根据原子簇化合物骨架的价电子结构及与配位体成键的性质,在确定原子簇骨架中存在的空轨道或孤对电子轨道数目后,按骨架价电子数目在骨架价成键轨道中的具体分配,推导了原子簇骨架的总键价数。再结合分子的几何构型,可以估计骨架中相邻原子间的成键情况。     

Is it True That the Normal Valence‐Length Correlation Is Irrelevant for Metal–Metal Bonds?

The most intriguing feature of metal–metal bonds in inorganic compounds is an apparent lack of correlation between the bond order and the bond length. In this study, we combine a variety of literature data obtained by quantum chemistry and our results based on the empirical bond valence model (BVM), to confirm for the first time the existence of a normal exponential correlation between the effective bond order (EBO) and the length of the metal–metal bonds. The difference between the EBO and the formal bond order is attributed to steric conflict between the (TM)_n cluster (TM=transition metal) and its environment. This conflict, affected mainly by structural type, should cause high lattice strains, but electron redistribution around TM atoms, evident from the BVM calculations, results in a full or partial strain relaxation.     

过渡金属络合物成键本质分析的常用方法

过渡金属络合物中过渡金属与配体间所形成的化学键的成键本质,可以在理论化学基础上,采用定量的方法进行分析。本文重点以铁羰基络合物为例,对常用的分析方法,如自然键轨道方法(NBO)、电荷分解分析(CDA)、分子中的原子(AIM)拓扑分析方法以及ETS和EDA能量分解方法等,在应用中的优缺点进行了分析和评述。借助于这些方法提供的电荷、能量和电子密度等配分项可以深刻认识和理解过渡金属-配体间形成的化学键的成键本质。     

过渡金属异核原子簇化学键研究 1: Ⅷ-Ⅷ, ⅥB-Ⅷ族双金属原子簇电子结构研究

本文对18个Ⅷ族双金属四面体簇和16个ⅥB-Ⅷ异金属四核簇进行了量子化学研究, 用DV-Xα方法讨论了它们的化学键、电荷转移、能级态密度。计算结果表明: Ⅷ族四面体簇需36个金属电子, 其中12个形成6个金属簇骼轨道, 24个与配体成键; ⅥB-Ⅷ异金属簇核中, 因两金属能带、电负性差异, ⅥB原子易向Ⅷ原子转移电荷, 环戊二烯基配体促进这一过程; 异金属簇能级总价带比单金属簇收缩, 而d能带比单金属簇展宽。     

Redox Potential and Crystal Chemistry of Hexanuclear Cluster Compounds

Most of TM₆-cluster compounds (TM = transition metal) are soluble in polar solvents, in which the cluster units commonly remain intact, preserving the same atomic arrangement as in solids. Consequently, the redox potential is often used to characterize structural and electronic features of respective solids. Although a high lability and variety of ligands allow for tuning of redox potential and of the related spectroscopic properties in wide ranges, the mechanism of this tuning is still unclear. Crystal chemistry approach was applied for the first time to clarify this mechanism. It was shown that there are two factors affecting redox potential of a given metal couple: Lever’s electrochemical parameters of the ligands and the effective ionic charge of TM, which in cluster compounds differs effectively from the formal value due to the bond strains around TM atoms. Calculations of the effective ionic charge of TMs were performed in the framework of bond valence model, which relates the valence of a bond to its length by simple Pauling relationship. It was also shown that due to the bond strains the charge depends mainly on the atomic size of the inner ligands.