Zn⋯Zn interactions at nickel and palladium centers

The analogy between ZnR fragments and the hydrogen radical represents a fruitful concept in organometallic synthesis. The organozinc(ii) and -zinc(i) sources ZnMe₂ (Me = methyl) and [Zn₂Cp∗₂] (Cp∗ = pentamethylcyclopentadienyl) provide one-electron fragments ·ZnR (R = Me, Cp∗), which can be trapped by transition metal complexes [L_aM], yielding [L_b(ZnR)_n]. The addition of the dizinc compound [Zn₂Cp∗₂] to coordinatively unsaturated [L_aM] by the homolytic cleavage of the Zn-Zn bond can be compared to the classic oxidative addition reaction of H₂, forming dihydride complexes [L_aM(H)₂]. It has also been widely shown that dihydrogen coordinates under preservation of the H-H bond in the case of certain electronic properties of the transition metal fragment. The σ-aromatic triangular clusters [Zn₃Cp∗₃]⁺ and [Zn₂CuCp∗₃] may be regarded as the first indication of this so far unknown, side-on coordination mode of [Zn₂Cp∗₂]. With this background in mind the question arises if a series of complexes featuring the Zn₂M structural motif can be prepared exhibiting a (more or less) intact Zn-Zn interaction, i.e. di-zinc complexes which are analogous to non-classical dihydrogen complexes of the Kubas type. In order to probe this idea, a series of interrelated organozinc nickel and palladium complexes and clusters were synthesized and characterized as model compounds: [Ni(ZnCp∗)(ZnMe)(PMe₃)₃] (1), [Ni(ZnCp∗)₂(ZnMe)₂(PMe₃)₂] (2), [{Ni(CN^tBu)₂(μ₂-ZnCp∗)(μ₂-ZnMe)}₂] (3), [Pd(ZnCp∗)₄(CN^tBu)₂] (4) and [Pd₃Zn₆(PCy₃)₂(Cp∗)₄] (5). The dependence of Zn⋯Zn interactions as a function of the ligand environments and the metal centers was studied. Experimental X-ray crystallographic structural data and DFT calculations support the analogy between dihydrogen and dizinc transition metal complexes.