While many FeFe-hydrogenase biomimetics are effective proton-reduction catalysts, few are active for H2 oxidation, and examples containing both a pendant amine group, able to act as a proton relay, and a second redox center, both essential features of the enzymes, are rare. Here we report the preparation and oxidation chemistry of two ferrocene-functionalized amino-diphosphines (PCNCP), (CH2PR2) 2NCH2Fc (R = Ph (1), Cy (2) ), and their ethylenedithiolate (edt) diiron complexes, Fe2 (CO) 4 (μ-edt) κ2- (R2PCH2) 2NCH2Fc (R = Ph (3), Cy (4) ). Their crystallographic characterization shows that PCNCP occupies an apical–basal position. CV responses are slightly R-dependent, showing for 3 and 4 in three separate oxidative processes assigned to successive one-electron oxidation of the diiron core (quasireversible), appended Fc (reversible), and the amine–diiron moiety (irreversible), as confirmed by IR and UV–Vis spectroelectrochemical studies supported by Density Functional Theory (DFT) and Time-dependent Density Functional Theory (TDDFT) calculations. The first oxidation results in a structural rearrangement of the Fe (PNP) (CO) unit and the formation of a semi-bridging carbonyl. Slow protonation of 3 with HBF4∙Et2O affords the corresponding N-protonated cation in acetone, whilst μ-hydride products dominate for both 3 and 4 in CD2Cl2. A preliminary H2 oxidation study was carried out with 3, and while there was some evidence of activity, it was much lower than reported for alkyl-functionalized PCNPC diiron derivatives.
Orton et al. (Mon,) studied this question.