Electronic communication in phosphine substituted bridged dirhenium complexes - clarifying ambiguities raised by the redox non-innocence of the C4H2- and C4-bridges.

he mononuclear rhenium carbyne complex trans-[Re(C=CSiMe3)(=C Me)(PMe3)(4)][PF6] (2) was prepared in 90% yield by heating a mixture of the dinitrogen complex trans-[ReCl(N-2)(PMe3)(4)] (1), TlPF6, and an excess of HC=CSiMe3. 2 could be deprotonated with KOtBu to the vinylidene complex trans-[Re(C=CSiMe3)(=C=CH2)(PMe3)(4)] (3) in 98% yield. Oxidation of 3 with 1.2 equiv. of [Cp2Fe][PF6] at -78 degrees C gave the C-beta-C-beta' coupled dinuclear rhenium biscarbyne complex trans-[(Me3SiC=C)(PMe3)(4)Re=C-CH2CH2-C=Re(PMe3)(4)(C=CSiMe3)][PF6](2) (5) in 92% yield. Deprotonation of 5 with an excess of KOtBu in THF produced the diamagnetic trans-[(Me3SiC=C)(PMe3)(4)Re=C=CH-CH=C=Re(PMe3)(4)(C=CSiMe3)] complex (E-6(S)) in 87% yield with an E-butadienediylidene bridge. Density functional theory (DFT) calculations of E-6(S) confirmed its singlet ground state. The Z-form of 6 (Z-6(S)) could not be observed, which is in accord with its DFT calculated 17.8 kJ mol(-1) higher energy. Oxidation of E-6 with 2 equiv. of [Cp2Fe] [PF6] resulted in the stable diamagnetic dicationic trans-[(Me3SiC=C)(PMe3)(4)Re=C-CH=CH-C=Re(PMe3)(4)(C=CSiMe3)][PF6](2) complex (E-6[PF6](2)) with an ethylenylidene dicarbyne structure of the bridge. The paramagnetic mixed-valence (MV) complex E-6[PF6] was obtained by comproportionation of E-6(S) and E-6[PF6](2) or by oxidation of E-6(S) with 1 equiv. of [Cp2Fe][PF6]. The dicationic trans-[(Me3SiC=C) (PMe3)(4)Re=C-C=C-C=Re(PMe3)(4)(C=CSiMe3)][PF6](2) (7[PF6](2)) complex, attributed a butynedi(triyl) bridge structure, was obtained by deprotonation of E-6[PF6](2) with KOtBu followed by oxidation with 2 equiv. of [Cp2Fe][PF6]. The neutral complex 7 could be accessed best by reduction of 7[PF6](2) with KH in the presence of 18-crown-6. According to DFT calculations 7 possesses two equilibrating electronic states: diamagnetic 7(S) and triplet 7(F) with ferromagnetically coupled spins. The latter is calculated to be 5.2 kcal mol(-1) lower in energy than 7(S). There is experimental evidence that 7(S) prevails in solution. 7 could not be isolated in the crystalline state and is unstable transforming mainly by H-abstraction to give E-6(S). UV-Vis-NIR spectroscopy for the dinuclear rhenium complexes E-6(S), E-6[PF6] and E-6[PF6](2), as well as EPR spectroscopic and variable-temperature magnetization measurements for the MV complex E-6[PF6] were also conducted. Spectro-electrochemical reduction studies on 7[PF6](2) allowed the characterization of the mono-and direduced forms of [7](+) and 7 by means of IR- and UV-Vis-NIR-spectroscopy and revealed the chemical fate of the higher reduced form.