Litcius/Paper detail

High-spin surface FeIV = O synthesis with molecular oxygen and pyrite for selective methane oxidation

Cancan Ling, Meiqi Li, Hao Li, Xiufan Liu, Furong Guo, Yi Liu, Rui Zhang, Jincai Zhao, Lizhi Zhang

2025Nature Communications14 citationsDOIOpen Access PDF

Abstract

Nature-inspired high-spin FeIV = O generation enables efficient ambient methane oxidation. By engineering sulfur-bridged dual ≡FeII…FeII≡ sites on pyrite (FeS2) mimicking soluble methane monooxygenase, we achieve O2-driven formation of high-spin (S = 2) surface FeIV = O species at room temperature and pressure. Strategic removal of bridging S atoms creates active sites that facilitate O2 activation via transient ≡Fe-O-O-Fe≡ intermediates, promoting homolytic O − O bond cleavage. The resulting FeIV = O exhibits an asymmetrically distorted coordination environment that reduces the crystal field splitting and favors the occupation of higher energy d-orbitals with unpaired electrons. Impressively, this configuration can efficiently convert CH4 to CH3OH through an oxygen transfer reaction with a synthetic efficiency of TOF = 27.4 h−1 and selectivity of 87.0%, outperforming most ambient O2-driven benchmarks under comparable conditions and even surpassing many H2O2-mediated systems. This study offers a facile method to synthesize high-spin surface FeIV = O and highlights the importance of metal spin state tailoring on non-enzymatic methane activation. High-spin Fe(IV) = O sites efficiently activate methane but are challenging to synthesize. This study develops dual Fe(II) sites on FeS2, generating high-spin Fe(IV) = O from O2, achieving superior methane-to-methanol conversion under mild conditions.

Topics & Concepts

MethaneUnpaired electronOxygenPyriteChemistryPhotochemistryHomolysisSpin statesBond cleavageMethane monooxygenaseSelectivityMetalRadicalCatalysisInorganic chemistryMineralogyOrganic chemistryCatalytic Processes in Materials ScienceIron oxide chemistry and applicationsMetal-Catalyzed Oxygenation Mechanisms
High-spin surface FeIV = O synthesis with molecular oxygen and pyrite for selective methane oxidation | Litcius