Wang, Longliang; Du, Haiyan; Xu, Huacheng; Li, Huan; Li, Lina

JOURNAL OF HAZARDOUS MATERIALS

2022, 439, 0304-3894

Wang, Longliang; Du, Haiyan; Xu, Huacheng; Li, Huan; Li, Lina

The oxygenation of Fe(II)-bearing minerals for hydroxyl radicals (HO.) formation and contaminant attenuation receive increasing attention, while the mechanisms for specific Fe(II) species in manipulating HO. formation and contaminant attenuation are unclear. Herein, a total of four Fe(III)-bearing minerals were applied in the reduction-oxygenation processes to produce HO.. Results showed that the total HO. generated from the Fe-(oxyhydr)oxides were significantly higher than those from the Fe-silicates, with the order of goethite and hematite (-1500 mu mol kg(-1)) > Fe-montmorillonite (-550 mu mol kg-1) > chlorite (-120 mu mol kg-1). The HO. for-mation was largely hinged on the reactive Fe(II) species, i.e., the surface-adsorbed/low-crystalline Fe(II) in the Fe-bearing minerals. For the co-incubation of minerals and phenanthrene, the concentrations of phenanthrene decreased from the initial 3.0 mg L-1 to 0.7 mg L-1 and 1.9 mg L-1 for Fe-montmorillonite and goethite, respectively, suggesting the HO & BULL; mediated by the Fe-montmorillonite was more conducive for phenanthrene attenuation. The goethite tended to promote the formation of free HO., while the Fe-montmorillonite with interlayer structure can provide attachment sites for the surface-adsorbed/low-crystalline Fe(II), resulting in high potential for surface-bound HO. formation and phenanthrene attenuation. This study highlights the importance of Fe-bearing minerals in manipulating HO' formation, providing new insight into the removal of contaminants in ecosystems.