化学
羟基自由基
有机质
天然有机质
生产(经济)
环境化学
废水
激进的
化学工程
水处理
作者
Qiang Zeng,Yifei Wu,Dafu Hu,Hailiang Dong
标识
DOI:10.1021/acs.est.5c17138
摘要
Ferrihydrite-organic matter (Fh-OM) coprecipitates, long regarded as key reservoirs for OM in redox-dynamic environments, are now recognized to transform OM through hydroxyl radical (•OH) generation during iron redox cycling. This study systematically examines •OH production mechanisms during the abiotic oxidation of reduced Fh-OM coprecipitates at different C/Fe ratios by using three representative OM types: citrate (organic acid), polygalacturonic acid (polysaccharide), and lignin, spanning a spectrum of chemical properties and origins of OM. We observed a two-stage oxidation pattern with distinct •OH production efficiencies, corresponding to heterogeneous and homogeneous Fe(II)-dominated oxidation pathways, respectively. At a low C/Fe ratio, OM increased •OH production by 48.9-98.1% through its Fe-chelating capacity. At a high C/Fe ratio, citrate and polygalacturonic acid suppressed •OH production by 22.2-28.6% through their •OH scavenging capacity; however, lignin increased •OH production by 36.8% due to its strong electron-donating capacity. Collectively, our results demonstrate that the C/Fe ratio and the chemical properties of OM, including Fe-chelating, electron-donating, and •OH scavenging capacities, are key controls of •OH yield during the abiotic oxidation of reduced Fh-OM coprecipitates. These findings underscore the critical role of OM in understanding •OH-mediated processes such as organic carbon turnover and contaminant degradation in redox-fluctuating environments.
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