Mild redox complementation enables H2 activation by [FeFe]-hydrogenase models

Abstract

Mild oxidants such as [Fe(C(5)Me(5))(2)](+) accelerate the activation of H(2) by [Fe(2)[(SCH(2))(2)NBn](CO)(3)(dppv)(PMe(3))](+) ([1](+)), despite the fact that the ferrocenium cation is incapable of oxidizing [1](+). The reaction is first-order in [1](+) and [H(2)] but independent of the E(1/2) and concentration of the oxidant. The analogous reaction occurs with D(2) and proceeds with an inverse kinetic isotope effect of 0.75(8). The activation of H(2) is further enhanced with the tetracarbonyl [Fe(2)[(SCH(2))(2)NBn](CO)(4)(dppn)](+) ([2](+)), the first crystallographically characterized model for the H(ox) state of the active site containing an amine cofactor. These studies point to rate-determining binding of H(2) followed by proton-coupled electron transfer. Relative to that by [1](+), the rate of H(2) activation by [2](+)/Fc(+) is enhanced by a factor of 10(4) at 25 °C.

Figure 1

Active site of the H_ox state of [FeFe]-hydrogenase (left) and the model [1]⁺ (right, R = CH₂Ph).

Figure 2

Structure of the cation in [Fe₂[(SCH₂)₂NBn](CO)₄(dppn)]BAr^F₄. Selected bond lengths: (Fe-N) = 3.234(3), (Fe-Fe) = 2.568(1), (Fe-P) = 2.231(1) Å.

Figure 3

IR spectra of a CH₂Cl₂ solution of [2]BAr^F₄ and [Fc]BAr^F₄ before (black) and 5 (red) and 14 min. (blue) after introducing H (1atm).

Figure 4

X-Band EPR spectrum of [2]BAr^F₄ (110 K, 1:1 CH₂Cl₂:toluene frozen solution). Parameters: g_z = 2.1260 with A_z(³¹P) = 78 MHz, g_x ≈ g_y = 2.0165 with A_x(³¹P) ≈ A_v(³¹P) = 79 MHz.

Scheme 1

Activation of H₂ by [1]⁺ and Cp*₂Fe⁺ to form [1H]⁺.

Scheme 2

The rate law for oxidation of H₂ by [1]⁺ and ferrocenium is consistent with the rate determining step being H₂ addition (step 1) or redox/heterolysis of the H₂ complex (step 2).