Photolytic, Pyrolytic and Trimethylamine N-Oxide Induced CO Removal from [BiFe4(CO)16]3–: Synthesis, X-Ray Crystal Structure and Properties of [N(PPh3)2]2[Bi2Fe5(CO)17]

Abstract

The formation of anionic-cluster species from compounds containing the ‘open’ (i.e. non-cluster) [BiFe₄(CO)₁₆]^3– (or [Bi{Fe(CO)₄}₄]^3–) ion following loss of CO as a result of photolytic, pyrolytic and chemical means has been investigated. Photolysis of salts of the [BiFe₄(CO)₁₆]^3– ion in acetonitrile, where the associated cations are [N(PPh₃)₂]⁺ or [NEt₄]⁺, produce a range of species including [Bi₂Fe₅(CO)₁₇]^2–, [Bi₂Fe₄(CO)₉]^2–, [Bi₂Fe₃(CO)₉]^2–, [Fe₂(CO)₈]^2– and [Fe₄(CO)₁₃]^2–, with the distribution of species being cation dependent. The previously unknown [Bi₂Fe₅(CO)₁₇]^2– ion was obtained as the [N(PPh₃)₂]⁺ salt, crystallizing in the triclinic space group P 1, with a 15.851(7), b 17.199(8), c 20.020(8) Å, α 114.72(2), β 95.51(3), γ 113.01(2)^o, Z 2 and V 4338(3) ų. The structure was determined by X-ray diffraction methods to an R of 0.035 (R_w = 0.040) for 6778 independent observed reflections. The anion consists of a central square-based pyramidal ‘nido-Bi₂[Fe(CO)₃]₃’ cluster unit, with two external Fe(CO)₄ fragments attached to the two trans four-coordinate bismuth atoms located in the base of the pyramid. A thermogravimetric study of [NEt₄]₃[BiFe₄(CO)₁₆] indicated decomposition above 150˚C, with an apparent loss of three CO molecules per [BiFe₄(CO)₁₆]^3– ion below 160˚C. Decomposition was complete by 205˚C and also involved pyrolysis of the [NEt₄]⁺ cations. Pyrolysis of solid [NEt₄]₃[BiFe₄(CO)₁₆] at 160˚C for several hours under N₂ implicated an intermediate species in the Bi/Fe carbonyl anion system, probably [Bi₂Fe₃(CO)9]^2–, in addition to the [Fe₂(CO)₈]^2– ion, although the final product obtained was found to be [Bi₂Fe₄(CO)₁₃]^2–. Reaction of [NEt₄]₃ [BiFe₄(CO)₁₆] with trimethylamine N-oxide in acetonitrile, in an attempt to selectively remove CO by chemical means, lead to the slow formation of [Bi₂Fe₄(CO)₁₃]^2– and a little [Bi₂Fe₅(CO)₁₇]^2–, although the [Bi₂Fe₅(CO)₁₇]^2– was observed to react slowly with (CH₃)₃NO to give [Bi₂Fe₄(CO)₁₃]^2– as the major product. Conversion of [Bi₂Fe₅(CO)₁₇]^2– to [Bi₂Fe₄(CO)₁₃]^2– is likely initiated through nucleophilic attack at the axial carbon site of a pendant Fe(CO)₄ group, according to extended-HÜckel molecular orbital calculations. Calculations also show that there is no instability introduced in having a second pendant Fe(CO)₄ attached to the central cluster unit, and the anion can be produced by reaction of [Bi₂Fe₄(CO)₁₃]^2– with Fe₂(CO)₉ in tetrahydrofuran, through the addition of an Fe(CO)₄ fragment to the three-coordinate bismuth atom in the anion. The other product of the reaction is volatile Fe(CO)₅, which is easily separated from the desired product.