Ebbe Nordlander

Bis(phosphinidene)-capped triiron carbonyl clusters, including electron rich derivatives formed by substitution with chelating diphosphines, have been prepared and examined as proton reduction catalysts. Treatment of the known cluster [Fe₃(CO)₉(µ₃-PPh)₂] (1) with various diphosphines in refluxing THF (for 5, refluxing toluene) afforded the new clusters [Fe₃(CO)₇(µ₃-PPh)₂(κ²-dppb)] (2), [Fe₃(CO)₇(µ₃-PPh)₂(κ²-dppv)] (3), [Fe₃(CO)₇(µ₃-PPh)₂(κ²-dppe)] (4) and [Fe₃(CO)₇(µ₃-PPh)₂(µ-κ²-dppf)] (5) in moderate yields, together with small amounts of the corresponding [Fe₃(CO)₈(µ₃-PPh)₂(κ¹-Ph₂PxPPh₂)] cluster (x = -C₄H₆-, -C₂H₂-, -C₂H₄-, -C₃H₆-, -C₅H₄FeC₅H₄-). The molecular structures of complexes 3 and 5 have been established by X-ray crystallography. Complexes 1–5 have been examined as proton reduction catalysts in the presence of p-toluenesulfonic acid (p-TsOH) in CH₂Cl₂. Cluster 1 exhibits two one-electron quasi-reversible reduction waves at –1.39 V (ΔE = 195 mV) and at –1.66 V (ΔE = 168 mV; potentials vs. Fc⁺/Fc). Upon addition of p-TsOH the unsubstituted cluster 1 shows a first catalytic wave at –1.57 V and two further proton reduction processes at –1.75 and –2.29 V, each with a good current response. The diphosphine-substituted derivatives of 1 are reduced at more negative potentials than the parent cluster 1. Clusters 2–4 each exhibit an oxidation at ca. +0.1 V and a reduction at ca. –1.6 V; for 4 conversion to a redox active successor species is seen upon both oxidation and reduction. Clusters 2–4 show catalytic waves in the presence of p-TsOH, with cluster 4 exhibiting the highest relative catalytic current (i^cat/i⁰ ≈ 57) in the presence of acid, albeit at a new third reduction process not observed for 2 and 3. Addition of the dppf ligand to the parent diphosphinidene cluster 1 gave cluster 5 which exhibited a single reduction process at –1.95 V and three oxidation processes, all at positive values as compared to 2–4. Cluster 5 showed only weak catalytic activity for proton reduction with p-TsOH. The bonding in 4 was investigated by DFT calculations, and the nature of the radical anion and dianion is discussed with respect to the electrochemical data.