Krapp Andreas, Pandey Krishna K, Frenking Gernot
School of Chemical Sciences, Devi Ahilya University Indore, Indore-452017, India.
J Am Chem Soc. 2007 Jun 20;129(24):7596-610. doi: 10.1021/ja0691324. Epub 2007 May 27.
The equilibrium geometries and bond dissociation energies of 16VE and 18VE complexes of ruthenium and iron with a naked carbon ligand are reported using density functional theory at the BP86/TZ2P level. Bond energies were also calculated at CCSD(T) using TZ2P quality basis sets. The calculations of [Cl2(PMe3)2Ru(C)] (1Ru), [Cl2(PMe3)2Fe(C)] (1Fe), [(CO)2(PMe3)2Ru(C)] (2Ru), [(CO)2(PMe3)2Fe(C)] (2Fe), [(CO)4Ru(C)] (3Ru), and [(CO)4Fe(C)] (3Fe) show that 1Ru has a very strong Ru-C bond which is stronger than the Fe-C bond in 1Fe. The metal-carbon bonds in the 18VE complexes 2Ru-3Fe are weaker than those in the 16VE species. Calculations of the related carbonyl complexes [(PMe3)2Cl2Ru(CO)] (4Ru), [(PMe3)2Cl2Fe(CO)] (4Fe), [(PMe3)2Ru(CO)3] (5Ru), [(PMe3)2Fe(CO)3] (5Fe), [Ru(CO)5] (6Ru), and [Fe(CO)5] (6Fe) show that the metal-CO bonds are much weaker than the metal-C bonds. The 18VE iron complexes have a larger BDE than the 18VE ruthenium complexes, while the opposite trend is calculated for the 16VE compounds. Charge and energy decomposition analyses (EDA) have been carried out for the calculated compounds. The Ru-C and Fe-C bonds in 1Ru and 1Fe are best described in terms of two electron-sharing bonds with sigma and pi symmetry and one donor-acceptor pi bond. The bonding situation in the 18 VE complexes 2Ru-3Fe is better described in terms of closed shell donor-acceptor interactions in accordance with the Dewar-Chatt-Duncanson model. The bonding analysis clearly shows that the 16VE carbon complexes 1Ru and 1Fe are much more strongly stabilized by metal-C sigma interactions than the 18VE complexes which is probably the reason why the substituted homologue of 1Ru could become isolated. The EDA calculations show that the nature of the TM-C and TM-CO binding interactions resembles each other. The absolute values for the energy terms which contribute to Delta(Eint) are much larger for the carbon complexes than for the carbonyl complexes, but the relative strengths of the energy terms are not very different from each other. The pi bonding contribution to the orbital interactions in the carbon complexes is always stronger than sigma bonding. There is no particular bonding component which is responsible for the reversal of the relative bond dissociation energies of the Ru and Fe complexes when one goes from the 16VE complexes to the 18VE species. That the 18 VE compounds have longer and weaker TM-C and TM-CO bonds than the respective 16 VE compounds holds for all complexes. This is because the LUMO in the 16 VE species is a sigma-antibonding orbital which becomes occupied in the 18 VE species.
采用密度泛函理论在BP86/TZ2P水平上报道了钌和铁与裸碳配体形成的16价电子和18价电子配合物的平衡几何结构和键解离能。还使用TZ2P质量基组在CCSD(T)水平上计算了键能。对[Cl2(PMe3)2Ru(C)] (1Ru)、[Cl2(PMe3)2Fe(C)] (1Fe)、[(CO)2(PMe3)2Ru(C)] (2Ru)、[(CO)2(PMe3)2Fe(C)] (2Fe)、[(CO)4Ru(C)] (3Ru)和[(CO)4Fe(C)] (3Fe)的计算表明,1Ru具有非常强的Ru-C键,其比1Fe中的Fe-C键更强。18价电子配合物2Ru - 3Fe中的金属 - 碳键比16价电子物种中的弱。对相关羰基配合物[(PMe3)2Cl2Ru(CO)] (4Ru)、[(PMe3)2Cl2Fe(CO)] (4Fe)、[(PMe3)2Ru(CO)3] (5Ru)、[(PMe3)2Fe(CO)3] (5Fe)、[Ru(CO)5] (6Ru)和[Fe(CO)5] (6Fe)的计算表明,金属 - CO键比金属 - C键弱得多。18价电子的铁配合物比18价电子的钌配合物具有更大的键解离能,而对于16价电子的化合物则计算出相反的趋势。已对计算出的化合物进行了电荷和能量分解分析(EDA)。1Ru和1Fe中的Ru - C键和Fe - C键最好用具有σ和π对称性以及一个供体 - 受体π键的两个电子共享键来描述。根据Dewar - Chatt - Duncanson模型,18价电子配合物2Ru - 3Fe中的键合情况用闭壳层供体 - 受体相互作用来描述更好。键合分析清楚地表明,16价电子的碳配合物1Ru和1Fe通过金属 - C σ相互作用比18价电子配合物更稳定,这可能是1Ru的取代同系物能够分离出来的原因。EDA计算表明,过渡金属-碳和过渡金属 - 羰基结合相互作用的性质彼此相似。对Δ(Eint)有贡献的能量项的绝对值对于碳配合物比对羰基配合物大得多,但能量项的相对强度彼此之间差异不是很大。π键对碳配合物中轨道相互作用的贡献总是强于σ键作用。当从16价电子配合物转变为18价电子物种时Ru和Fe配合物相对键解离能的反转没有特定的键合成分负责。对于所有配合物,18价电子化合物比相应的16价电子化合物具有更长且更弱的过渡金属 - 碳和过渡金属 - 羰基键。这是因为16价电子物种中的最低未占分子轨道(LUMO)是一个σ反键轨道,其在18价电子物种中被占据。
