In-situ fabrication of supported iron oxides from synthetic acid mine drainage: High catalytic activities and good stabilities towards electro-Fenton reaction

•In-situ fabricate heterogeneous electro-Fenton catalyst from acid mine drainage.•Nano-scaled iron oxide/GF composites are obtained using an air-cathode fuel cell.•Fe3O4/GF exhibits higher electro-Fenton activity than Fe2O3/GF and FeOOH/GF.•Decomposition of H2O2 on iron oxides is completely surface-...

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Published in:Applied catalysis. B, Environmental Environmental, 2015-04, Vol.165, p.103-110
Main Authors: Sun, Min, Ru, Xiao-Rui, Zhai, Lin-Feng
Format: Article
Language:English
Subjects:
Acid mine drainage
Air-cathode fuel cell
Catalysis
Catalysts
Catalytic activity
Cathodes
Fuel cells
Hydrogen radical
Iron
Iron oxides
Recovery
RhB degradation, Surface-catalyzed
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creator Sun, Min
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Zhai, Lin-Feng
description •In-situ fabricate heterogeneous electro-Fenton catalyst from acid mine drainage.•Nano-scaled iron oxide/GF composites are obtained using an air-cathode fuel cell.•Fe3O4/GF exhibits higher electro-Fenton activity than Fe2O3/GF and FeOOH/GF.•Decomposition of H2O2 on iron oxides is completely surface-catalysis controlled.•Iron oxides maintain structures and show stabilities in recycling utilization. Acid mine drainage (AMD) contains a large amount of ferrous iron and the recovery of iron oxides from the AMD has been of extensive research interest. Here we report a novel air-cathode fuel cell strategy to in-situ utilize ferrous iron in the AMD for the fabrication of heterogeneous electro-Fenton catalysts. Three types of nano-structured iron oxide/graphite felt (GF) composites, including FeOOH/GF, Fe2O3/GF and Fe3O4/GF, were fabricated from a synthetic AMD and their catalytic activities towards the electro-Fenton reaction were evaluated at neutral pH with Rhodamine B (RhB) as a probe pollutant. The electro-Fenton system with GF cathode only removed 30±1.4% of RhB after 120min of reaction. In comparison, RhB removal efficiencies were significantly improved to 62.5±2.0%, 95.4±0.9% and 95.6±0.7% when the FeOOH/GF, Fe2O3/GF and Fe3O4/GF composites were used as the cathodes, respectively. Among the three types of composites, the Fe3O4/GF exhibited the highest electro-Fenton catalytic activity whereas the lowest activity was observed for the FeOOH/GF. The decomposition of H2O2 on the iron oxides followed a completely surface-catalyzed mechanism in which the iron oxides maintained their structures without leaching of iron species. The air-cathode fuel cell technology has a potential for iron recovery from the AMD, and provides an effective way for fabricating heterogeneous electro-Fenton catalyst with high catalytic activity and good stability.
doi_str_mv 10.1016/j.apcatb.2014.09.077
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Acid mine drainage (AMD) contains a large amount of ferrous iron and the recovery of iron oxides from the AMD has been of extensive research interest. Here we report a novel air-cathode fuel cell strategy to in-situ utilize ferrous iron in the AMD for the fabrication of heterogeneous electro-Fenton catalysts. Three types of nano-structured iron oxide/graphite felt (GF) composites, including FeOOH/GF, Fe2O3/GF and Fe3O4/GF, were fabricated from a synthetic AMD and their catalytic activities towards the electro-Fenton reaction were evaluated at neutral pH with Rhodamine B (RhB) as a probe pollutant. The electro-Fenton system with GF cathode only removed 30±1.4% of RhB after 120min of reaction. In comparison, RhB removal efficiencies were significantly improved to 62.5±2.0%, 95.4±0.9% and 95.6±0.7% when the FeOOH/GF, Fe2O3/GF and Fe3O4/GF composites were used as the cathodes, respectively. Among the three types of composites, the Fe3O4/GF exhibited the highest electro-Fenton catalytic activity whereas the lowest activity was observed for the FeOOH/GF. The decomposition of H2O2 on the iron oxides followed a completely surface-catalyzed mechanism in which the iron oxides maintained their structures without leaching of iron species. 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B, Environmental</title><description>•In-situ fabricate heterogeneous electro-Fenton catalyst from acid mine drainage.•Nano-scaled iron oxide/GF composites are obtained using an air-cathode fuel cell.•Fe3O4/GF exhibits higher electro-Fenton activity than Fe2O3/GF and FeOOH/GF.•Decomposition of H2O2 on iron oxides is completely surface-catalysis controlled.•Iron oxides maintain structures and show stabilities in recycling utilization. Acid mine drainage (AMD) contains a large amount of ferrous iron and the recovery of iron oxides from the AMD has been of extensive research interest. Here we report a novel air-cathode fuel cell strategy to in-situ utilize ferrous iron in the AMD for the fabrication of heterogeneous electro-Fenton catalysts. Three types of nano-structured iron oxide/graphite felt (GF) composites, including FeOOH/GF, Fe2O3/GF and Fe3O4/GF, were fabricated from a synthetic AMD and their catalytic activities towards the electro-Fenton reaction were evaluated at neutral pH with Rhodamine B (RhB) as a probe pollutant. The electro-Fenton system with GF cathode only removed 30±1.4% of RhB after 120min of reaction. In comparison, RhB removal efficiencies were significantly improved to 62.5±2.0%, 95.4±0.9% and 95.6±0.7% when the FeOOH/GF, Fe2O3/GF and Fe3O4/GF composites were used as the cathodes, respectively. Among the three types of composites, the Fe3O4/GF exhibited the highest electro-Fenton catalytic activity whereas the lowest activity was observed for the FeOOH/GF. The decomposition of H2O2 on the iron oxides followed a completely surface-catalyzed mechanism in which the iron oxides maintained their structures without leaching of iron species. 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B, Environmental</jtitle><date>2015-04-01</date><risdate>2015</risdate><volume>165</volume><spage>103</spage><epage>110</epage><pages>103-110</pages><issn>0926-3373</issn><eissn>1873-3883</eissn><abstract>•In-situ fabricate heterogeneous electro-Fenton catalyst from acid mine drainage.•Nano-scaled iron oxide/GF composites are obtained using an air-cathode fuel cell.•Fe3O4/GF exhibits higher electro-Fenton activity than Fe2O3/GF and FeOOH/GF.•Decomposition of H2O2 on iron oxides is completely surface-catalysis controlled.•Iron oxides maintain structures and show stabilities in recycling utilization. Acid mine drainage (AMD) contains a large amount of ferrous iron and the recovery of iron oxides from the AMD has been of extensive research interest. Here we report a novel air-cathode fuel cell strategy to in-situ utilize ferrous iron in the AMD for the fabrication of heterogeneous electro-Fenton catalysts. Three types of nano-structured iron oxide/graphite felt (GF) composites, including FeOOH/GF, Fe2O3/GF and Fe3O4/GF, were fabricated from a synthetic AMD and their catalytic activities towards the electro-Fenton reaction were evaluated at neutral pH with Rhodamine B (RhB) as a probe pollutant. The electro-Fenton system with GF cathode only removed 30±1.4% of RhB after 120min of reaction. In comparison, RhB removal efficiencies were significantly improved to 62.5±2.0%, 95.4±0.9% and 95.6±0.7% when the FeOOH/GF, Fe2O3/GF and Fe3O4/GF composites were used as the cathodes, respectively. Among the three types of composites, the Fe3O4/GF exhibited the highest electro-Fenton catalytic activity whereas the lowest activity was observed for the FeOOH/GF. The decomposition of H2O2 on the iron oxides followed a completely surface-catalyzed mechanism in which the iron oxides maintained their structures without leaching of iron species. 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subjects Acid mine drainage
Air-cathode fuel cell
Catalysis
Catalysts
Catalytic activity
Cathodes
Fuel cells
Hydrogen radical
Iron
Iron oxides
Recovery
RhB degradation, Surface-catalyzed
title In-situ fabrication of supported iron oxides from synthetic acid mine drainage: High catalytic activities and good stabilities towards electro-Fenton reaction
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