Fischer–Hafner synthesis Also known as reductive Friedel–Crafts reaction, the
Fischer–Hafner synthesis entails treatment of metal chlorides with arenes in the presence of
aluminium trichloride and
aluminium metal. The method was demonstrated in the 1950s with the synthesis of
bis(benzene)chromium by Walter Hafner and his advisor
E. O. Fischer. The method has been extended to other metals, e.g. [Ru(C6Me6)2]2+. In this reaction, the AlCl3 serves to remove chloride from the metal precursor, and the Al metal functions as the reductant. The Fischer-Hafner synthesis is limited to arenes lacking sensitive functional groups. .
Direct synthesis Although many metal-arene complexes are robust, few are prepared by the direct reaction of arenes with metal salts. The main example is provided by silver perchlorate (and related salts), which dissolve in liquid arenes and crystallize with arene ligands. The strength of the metal-arene interaction is weak as indicated by the long Ag-C bond lengths and the nearly unperturbed nature of the arene. By
metal vapor synthesis, metal atoms co-condensed with arenes react to give complexes of the type M(arene)2. Cr(C6H6)2 can be produced by this method. :BrMn(CO)5 + Ag+ + C6R6 → [Mn(C6R6)(CO)3]+ + AgBr + 2 CO
From hexadienes Few Ru(II) and Os(II) complexes react directly with arenes. Instead, arene complexes of these metals are typically prepared by treatment of M(III) precursors with
cyclohexadienes. For example, heating alcohol solutions of 1,3- or 1,4-cyclohexadiene and
ruthenium trichloride gives
(benzene)ruthenium dichloride dimer. The conversion entails dehydrogenation of an intermediate diene complex.
Alkyne trimerization Metal complexes are known to catalyze
alkyne trimerization to give arenes. These reactions have been used to prepare arene complexes. Illustrative is the reaction of [Co(mesitylene)2]+ with
2-butyne to give [Co(C6Me6)2]+. ==Structure==