Qin Zhen-Zhen, Wang Qiang, Yuan Caixia, Yang Yun-Tao, Zhao Xue-Feng, Li Debao, Liu Ping, Wu Yan-Bo
Key Lab of Materials for Energy Conversion and Storage of Shanxi Province, Institute of Molecular Science, Shanxi University, Taiyuan, Shanxi 030006, China.
Dalton Trans. 2018 Mar 26;47(13):4707-4713. doi: 10.1039/c7dt04897a.
Though ultrashort metal-metal distances (USMMD, dM-M < 1.900 Å) were primarily realized between transition metals, USMMDs between main group metal atoms such as beryllium atoms have also been designed previously using two strategies: (1) formation of multiple bonding orbitals or (2) having favourable electrostatic attraction. We recently turned our attention to the reported species IH → Be2H2 ← IH (where IH denotes imidazol-2-ylidene) because the orbital energy level of its π-type HOMO is noted to be very high, which may result in intrinsic instability. In the present study, we combined the abovementioned strategies to solve the high orbital energy level problem without losing the ultrashort Be-Be distances. It was found that breaking of such π-type HOMO by addition of a -CH2- group onto the bridging position of two beryllium atoms led to the formation of IH → Be2H2CH2 ← IH species, which not only possesses an ultrashort Be-Be distance in the -Be2H2CH2- moiety, but also has a relatively low HOMO energy level. Replacing the IH ligands with NH3 and PH3 resulted in the formation of NH3 → Be2H2CH2 ← NH3 and PH3 → Be2H2CH2 ← PH3 species with similar features. The electronic structure analyses suggest that the ultrashort Be-Be distances in these species are achieved by the combined effects of the formation of two Be-H-Be 3c-2e bonds and having favourable Coulombic attractions between the carbon atom of the -CH2- group and two beryllium atoms. Remarkably, when the IH, NH3, and PH3 ligands were replaced by large ligands with bulky groups, such as 1,3-bis(2,6-diisopropyl phenyl)imidazol-2-ylidene (IDip), triphenylamine (NPh3), and triphenylphoshpine (PPh3), respectively, the resultant species IDip → Be2H2CH2 ← IDip, NPh3 → Be2H2CH2 ← NPh3, and PPh3 → Be2H2CH2 ← PPh3 exhibit good steric protection around the -Be2H2CH2- core. These species are thus examples for the experimental realization of species with ultrashort metal-metal distances between main group metals.
尽管超短金属-金属距离(USMMD,dM-M < 1.900 Å)最初主要在过渡金属之间实现,但之前也已通过两种策略设计出主族金属原子(如铍原子)之间的超短金属-金属距离:(1)形成多个成键轨道或(2)具有有利的静电吸引力。我们最近将注意力转向了已报道的物种IH → Be2H2 ← IH(其中IH表示咪唑-2-亚基),因为其π型最高占据分子轨道(HOMO)的轨道能级被认为非常高,这可能导致其内在不稳定性。在本研究中,我们结合上述策略来解决高轨道能级问题,同时又不失去超短的Be-Be距离。研究发现,通过在两个铍原子的桥连位置添加一个-CH2-基团来破坏这种π型HOMO,会导致形成IH → Be2H2CH2 ← IH物种,该物种不仅在-Be2H2CH2-部分具有超短的Be-Be距离,而且具有相对较低的HOMO能级。用NH3和PH3取代IH配体会导致形成具有类似特征的NH3 → Be2H2CH2 ← NH3和PH3 → Be2H2CH2 ← PH3物种。电子结构分析表明,这些物种中超短的Be-Be距离是通过形成两个Be-H-Be 3c-2e键以及-CH2-基团的碳原子与两个铍原子之间具有有利的库仑吸引力的综合作用实现的。值得注意的是,当分别用带有庞大基团的大配体(如1,3-双(2,6-二异丙基苯基)咪唑-2-亚基(IDip)、三苯胺(NPh3)和三苯基膦(PPh3))取代IH、NH3和PH3配体时,所得物种IDip → Be2H2CH2 ← IDip、NPh3 → Be2H2CH2 ← NPh3和PPh3 → Be2H2CH2 ← PPh3在-Be2H2CH2-核心周围表现出良好的空间保护。因此,这些物种是在主族金属之间实现具有超短金属-金属距离的物种的实验实例。
