Modeling the Signatures of Hydrides in Metalloenzymes: ENDOR analysis of a di-iron Fe(μ-NH)(μ-H)Fe core

The application of 35 GHz pulsed EPR and ENDOR spectroscopies has established that the biomimetic model complex L3Fe(μ-NH)(μ-H)FeL3 (L3 = [PhB(CH2PPh2)3]−) complex, 3, is a novel S = 1/2 type-III mixed-valence di-iron II/III species, in which the unpaired electron is shared equally between the two iron centers. 1,2H and 14,15N ENDOR measurements of the bridging imide are consistent with an allyl radical molecular orbital model for the two bridging ligands. Both the (μ-H) and the proton of the (μ-NH) of the crystallographically characterized 3 show the proposed signature of a ‘bridging’ hydride that is essentially equidistant between two ‘anchor’ metal ions: a rhombic dipolar interaction tensor, T ≈ [T, –T, 0]. The point-dipole model for describing the anisotropic interaction of a bridging H as the sum of the point-dipole couplings to the ‘anchor’ metal ions reproduces this signature with high accuracy, as well as the axial tensor of a terminal hydride, T ≈ [−T, –T, 2T], thus validating both the model and ...