Abstract
Metalloenzymes use second coordination sphere (SCS) hydrogen bond (H-bond) donors and acceptors to facilitate small molecule activation by lowering the activation energies for chemical transformations or by stabilizing reactive intermediates. Borovik and co-workers studied the role of SCS groups in dioxygen and chalcogen activation in well-defined mononuclear model complexes. Here, we use the same complex, K[Fe
(H
L)], to study the role of H-bonding for nitric oxide (NO) activation. Remarkably, in solution, K[Fe
(H
L)] is capable of direct NO reduction to nitrous oxide (N
O) at a single Fe center. Initial formation of a hs-{FeNO}
intermediate is followed by fast attack by a second NO molecule to form N
O and a putative Fe
═O intermediate, which then undergoes multiple decomposition pathways, forming an antiferromagnetically coupled
= 1/2 Fe
/Fe
dimer and a diamagnetic diferric species as confirmed by Mössbauer and EPR spectroscopy. Notably, in the absence of the SCS H-bond donors, only the formation of a stable hs-{FeNO}
species is observed. Intermediates of NO reduction were observed by reacting K[Fe
(H
L)] in the solid state with NO, which leads to the formation of hs-{FeNO}
species, N
O, and the Fe
═O intermediate, as confirmed by IR spectroscopy. To the best of our knowledge, direct reduction of NO at a single Fe center has not been reported. Furthermore, the ability to form a high-valent metal-oxo species directly from NO is unprecedented for nonheme iron chemistry. This novel reactivity has significant implications in biology and for catalytic systems for NO
reduction.