School of Chemistry, Monash University, PO Box 23, Melbourne, VIC, 3800, Australia.
Chemistry. 2011 Jan 24;17(4):1294-303. doi: 10.1002/chem.201002388. Epub 2010 Nov 30.
Reactions of lithium complexes of the bulky guanidinates {(Dip)N}(2)CNR(2) (Dip=C(6)H(3)iPr(2)-2,6; R=C(6)H(11) (Giso(-)) or iPr (Priso(-)), with NiBr(2) have afforded the nickel(II) complexes [{Ni(L)(μ-Br)}(2)] (L=Giso(-) or Priso(-)), the latter of which was crystallographically characterized. Reduction of [{Ni(Priso)(μ-Br)}(2)] with elemental potassium in benzene or toluene afforded the diamagnetic species [{Ni(Priso)}(2)(μ-C(6)H(5)R)] (R=H or Me), which were shown, by X-ray crystallographic studies, to possess nonplanar bridging arene ligands that are partially reduced. A similar reduction of [{Ni(Priso)(μ-Br)}(2)] in cyclohexane yielded a mixture of the isomeric complexes [{Ni(μ-κ(1)-N-,η(2)-Dip-Priso)}(2)] and [{Ni(μ-κ(2)-N,N'-Priso)}(2)], both of which were structurally characterized. These complexes were also formed through arene elimination processes if [{Ni(Priso)}(2)(μ-C(6)H(5)R)] (R=H or Me) were dissolved in hexane. In that solvent, diamagnetic [{Ni(μ-κ(1)-N-,η(2)-Dip-Priso)}(2)] was found to slowly convert to paramagnetic [{Ni(μ-κ(2)-N,N'-Priso)}(2)], suggesting that the latter is the thermodynamic isomer. Computational analysis of a model of [{Ni(μ-κ(2)-N,N'-Priso)}(2)] showed it to have a Ni-Ni bond that has a multiconfigurational electronic structure. An analogous copper(I) complex [{Cu(μ-κ(2)-N,N'-Giso)}(2)] was prepared, structurally authenticated, and found, by a theoretical study, to have a negligible Cu···Cu bonding interaction. The reactivity of [{Ni(Priso)}(2)(μ-C(6)H(5)Me)] and [{Ni(μ-κ(2)-N,N'-Priso)}(2)] towards a range of small molecules was examined and this gave rise to diamagnetic complexes [{Ni(Priso)(μ-CO)}(2)] and [{Ni(Priso)(μ-N(3))}(2)]. Taken as a whole, this study highlights similarities between bulky guanidinate ligands and the β-diketiminate ligand class, but shows the former to have greater coordinative flexibility.
锂配合物{(Dip)N}(2)CNR(2)(Dip=C(6)H(3)iPr(2)-2,6;R=C(6)H(11)(Giso(-))或 iPr(Priso(-)))与 NiBr(2)反应,生成镍(II)配合物[{Ni(L)(μ-Br)}(2)](L=Giso(-)或 Priso(-)),后者通过晶体学表征。在苯或甲苯中用元素钾还原[{Ni(Priso)(μ-Br)}(2)]生成反磁性物种[{Ni(Priso)}(2)(μ-C(6)H(5)R)](R=H 或 Me),通过 X 射线晶体学研究表明,它们具有部分还原的非平面桥联芳基配体。在环己烷中类似地还原[{Ni(Priso)(μ-Br)}(2)]得到了 [{Ni(μ-κ(1)-N-,η(2)-Dip-Priso)}(2)]和[{Ni(μ-κ(2)-N,N'-Priso)}(2)]的异构体配合物的混合物,两者均通过结构表征。如果 [{Ni(Priso)}(2)(μ-C(6)H(5)R)](R=H 或 Me)溶解在己烷中,也会通过芳环消除过程形成这些配合物。在该溶剂中,发现反磁性[{Ni(μ-κ(1)-N-,η(2)-Dip-Priso)}(2)]缓慢转化为顺磁性[{Ni(μ-κ(2)-N,N'-Priso)}(2)],表明后者是热力学异构体。对 [{Ni(μ-κ(2)-N,N'-Priso)}(2)]模型的计算分析表明,它具有具有多组态电子结构的 Ni-Ni 键。制备了类似的铜(I)配合物[{Cu(μ-κ(2)-N,N'-Giso)}(2)],通过结构鉴定,并通过理论研究发现,其 Cu···Cu 键合相互作用可以忽略不计。 [{Ni(Priso)}(2)(μ-C(6)H(5)Me)]和[{Ni(μ-κ(2)-N,N'-Priso)}(2)]对一系列小分子的反应性进行了研究,得到了反磁性配合物[{Ni(Priso)(μ-CO)}(2)]和[{Ni(Priso)(μ-N(3))}(2)]。总的来说,这项研究强调了大体积胍基配体与β-二酮亚胺配体类的相似性,但表明前者具有更大的配位灵活性。
