Mechanism of Nitrogen Reduction to Ammonia in a Diiron Model of Nitrogenase

Barchenko, Maxim; O’Malley, Patrick J.; de Visser, Sam P.

doi:10.1021/acs.inorgchem.3c02089

Inorg. Chem.

2023

DOI: 10.1021/acs.inorgchem.3c02089

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Mechanism of Nitrogen Reduction to Ammonia in a Diiron Model of Nitrogenase

Maxim Barchenko,

Patrick J. O’Malley,

Sam P. de Visser

Abstract: Nitrogenase is a fascinating enzyme in biology that reduces dinitrogen from air to ammonia through stepwise reduction and protonation. Despite it being studied in detail by experimental and computational groups, there are still many unknown factors in the catalytic cycle of nitrogenase, especially related to the addition of protons and electrons and their order. A recent biomimetic study characterized a potential dinitrogen-bridged diiron cluster as a synthetic model of nitrogenase. Using strong acid and reduc… Show more

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2024

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Biomimetic [MFe₃S₄]³⁺ Cubanes (M = V/Mo) as Catalysts for a Fischer–Tropsch-like Hydrocarbon Synthesis─A Computational Study

Barchenko,

Malcomson,

O’Malley

et al. 2024

Inorg. Chem.

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Nitrogenase is the enzyme primarily responsible for reducing atmospheric nitrogen to ammonia. There are three general forms of nitrogenase based on the metal ion present in the cofactor binding site, namely, molybdenum-dependent nitrogenases with the iron−molybdenum cofactor (FeMoco), the vanadium-dependent nitrogenases with FeVco, and the iron-only nitrogenases. It has been shown that the vanadium-dependent nitrogenases tend to have a lesser efficacy in reducing dinitrogen but a higher efficacy in binding and reducing carbon monoxide. In biomimetic chemistry, [MFe 3 S 4 ] (M = Mo/V) cubanes have been synthesized, studied, and shown to be promising mimics of some of the geometric and electronic properties of the nitrogenase cofactors. In this work, a density functional theory (DFT) study is presented on Fischer−Tropsch catalysis by these cubane complexes by studying CO binding and reduction to hydrocarbons. Our work implies that molybdenum has stronger binding interactions with the iron−sulfur framework of the cubane, which results in easier reduction of substrates like N 2 H 4 . However, this inhibits the binding and activation of CO, and hence, the molybdenum-containing complexes are less suitable for Fischer−Tropsch catalysis than vanadium-containing complexes.

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Biomimetic [MFe₃S₄]³⁺ Cubanes (M = V/Mo) as Catalysts for a Fischer–Tropsch-like Hydrocarbon Synthesis─A Computational Study

Barchenko,

Malcomson,

O’Malley

et al. 2024

Inorg. Chem.

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show abstract

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Mechanism of Nitrogen Reduction to Ammonia in a Diiron Model of Nitrogenase

Cited by 1 publication

References 74 publications

Biomimetic [MFe₃S₄]³⁺ Cubanes (M = V/Mo) as Catalysts for a Fischer–Tropsch-like Hydrocarbon Synthesis─A Computational Study

Biomimetic [MFe₃S₄]³⁺ Cubanes (M = V/Mo) as Catalysts for a Fischer–Tropsch-like Hydrocarbon Synthesis─A Computational Study

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Mechanism of Nitrogen Reduction to Ammonia in a Diiron Model of Nitrogenase

Cited by 1 publication

References 74 publications

Biomimetic [MFe3S4]3+ Cubanes (M = V/Mo) as Catalysts for a Fischer–Tropsch-like Hydrocarbon Synthesis─A Computational Study

Biomimetic [MFe3S4]3+ Cubanes (M = V/Mo) as Catalysts for a Fischer–Tropsch-like Hydrocarbon Synthesis─A Computational Study

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Biomimetic [MFe₃S₄]³⁺ Cubanes (M = V/Mo) as Catalysts for a Fischer–Tropsch-like Hydrocarbon Synthesis─A Computational Study

Biomimetic [MFe₃S₄]³⁺ Cubanes (M = V/Mo) as Catalysts for a Fischer–Tropsch-like Hydrocarbon Synthesis─A Computational Study