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Natural Organic Matter Association Modulates Pyrite Surface Electron Transfer Kinetics and Path for Reactive Oxygen Species Generation

Mengxi Tan, Chen Hong, Xiaoshan Zheng, Baoliang Chen, C. Chu

2026Environmental Science & Technology6 citationsDOI

Abstract

Surface electron transfer from iron minerals to molecular oxygen (O 2 ) has been identified as a pivotal natural source of reactive oxygen species (ROS). In water and soils, iron minerals are often associated with natural organic matter (NOM), which can substantially influence surface redox reactions. Yet inconsistencies remain in understanding the impacts of NOM association on ROS production from iron mineral surfaces due to limited insight into surface interfacial electron transfer processes. Here, we show that NOM association significantly modulates both the kinetics and the path of electron transfer on pyrite surfaces. Steric hindrance at O 2 adsorption sites decreased the electron transfer rate by 22.7–38.6%, from 4.4 × 10 –4 to 2.7–3.4 × 10 –4 s –1 . Concomitantly, O 2 reduction shifted from a four-electron path producing H 2 O to a two-electron path favoring H 2 O 2 formation, increasing H 2 O 2 selectivity from 29.6% on pristine pyrite to 49.2–67.1% on NOM-associated pyrite. These changes collectively enhanced ROS production, with H 2 O 2 and •OH yields increasing by 1.5–1.9-fold and 1.8–2.3-fold, respectively. Elevated ROS levels increased organic pollutant degradation rates by 1.6–2.7-fold. These findings highlight the multifaceted role of the NOM in shaping surface electron transfer kinetics and ROS generation at iron mineral interfaces.

Topics & Concepts

ChemistryElectron transferPyriteRedoxKineticsNatural organic matterOxygenReactive oxygen speciesAdsorptionSteric effectsInorganic chemistryPhotochemistryEnvironmental chemistryMineralDegradation (telecommunications)Organic matterSulfurPollutantElectron transport chainReaction rateChemical engineeringSurface waterOxygen evolutionMetalZerovalent ironAdvanced oxidation water treatmentMetal Extraction and BioleachingMicrobial Fuel Cells and Bioremediation