Abstract

Group 13 M(I) compounds often disproportionate into M(0) and M(III). Here, however, we show that the reaction of the M(I) salt of the weakly coordinating alkoxyaluminate [Ga(I)(C6H5F)2](+)[Al(OR(F))4](-) (R(F)=C(CF3)3) with 2,2'-bipyridine (bipy) yields the paramagnetic and distorted octahedral [Ga(bipy)3](2+)(•){[Al(OR(F))4](-)}2 complex salt. While the latter appears to be a Ga(II) compound, both, EPR and DFT investigations assign a ligand-centred [Ga(III){(bipy)3}(•)](2+) radical dication. Surprisingly, the application of the heavier homologue [(I)n(I)(C6H5F)2](+)[Al(OR(F))4](-) leads to aggregation and formation of the homonuclear cationic triangular and rhombic [In3(bipy)6](3+), [In3(bipy)5](3+) and [In4(bipy)6](4+) metal atom clusters. Typically, such clusters are formed under strongly reductive conditions. Analysing the unexpected redox-neutral cationic cluster formation, DFT studies suggest a stepwise formation of the clusters, possibly via their triplet state and further investigations attribute the overall driving force of the reactions to the strong In-In bonds and the high lattice enthalpies of the resultant ligand stabilized [M3](3+){[Al(OR(F))4](-)}3 and [M4](4+){[Al(OR(F))4](-)}4 salts.