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Generation and Reactivity of a High-Spin Iron(IV)-Oxo Complex That Is Stable at Ambient Temperatures

Christopher Hastings, Lucy Huffman, William W. Brennessel, Brandon R. Barnett

2025Journal of the American Chemical Society10 citationsDOIOpen Access PDF

Abstract

High Resolution Image Download MS PowerPoint Slide Nature operates a variety of challenging oxidation reactions through intermediates bearing tetravalent iron centers bound to a terminal oxo ligand. The high-spin ( S = 2) electronic configuration is believed to be particularly important in C–H activation reactions mediated by iron(IV)-oxo species. Coordination environments that promote high-spin ground states obviate the need for spin-state crossing to access this state and can promote rapid oxidation reactivity. As a result, however, synthetic iron(IV)-oxo species with S = 2 ground states tend to exhibit poor thermal stabilities, which has hampered a broader elucidation of their reactivity profiles. In this work, we report the synthesis of a remarkably stable high-spin iron(IV)-oxo complex that localizes the Fe═O unit within a rigid organic macrocycle. This design results in essentially unlimited stability at ambient temperatures and a half-life of 21 h at 70 °C in CH 3 CN, endowing this compound with the highest thermal stability for a high-spin Fe IV ═O complex reported to date. The ligand’s steric profile shuts down intermolecular reactivity with potential O atom acceptors and hydrocarbons bearing weak C–H bonds, but proton-coupled electron transfer reactivity with 2,4,6-tri- tert -butylphenol (TTBP) occurs readily at room temperature despite its steric bulk.

Topics & Concepts

ChemistryReactivity (psychology)Spin (aerodynamics)Chemical physicsThermodynamicsAlternative medicinePhysicsPathologyMedicineMetal-Catalyzed Oxygenation MechanismsPorphyrin and Phthalocyanine ChemistryHemoglobin structure and function
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