Cu-Doped Fe@Fe<sub>2</sub>O<sub>3</sub> core–shell nanoparticle shifted oxygen reduction pathway for high-efficiency arsenic removal in smelting wastewater

Haopeng Feng; Lin Tang; Jing Tang; Guangming Zeng; Haoran Dong; Yaocheng Deng; Longlu Wang; Yani Liu; Xiaoya Ren; Yaoyu Zhou

doi:10.1039/c8en00348c

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Cu-Doped Fe@Fe₂O₃ core–shell nanoparticle shifted oxygen reduction pathway for high-efficiency arsenic removal in smelting wastewater

Haopeng Feng Lin Tang Jing Tang Guangming Zeng Haoran Dong Yaocheng Deng Longlu Wang Yani Liu Xiaoya Ren Yaoyu Zhou

Year: 2018 Journal: Environmental Science Nano Vol: 5 (7)Pages: 1595-1607 Publisher: Royal Society of Chemistry

DOI: 10.1039/c8en00348c

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Abstract

Studies on the removal of As(iii) by Fe-based materials have been carried out for decades, but the time-consuming process and low removal capacity are obstacles for large-scale practical applications.

Keywords:

Arsenic Materials science Nanoparticle Doping Smelting Wastewater Chemical engineering Sulfur Oxygen Core (optical fiber) Inorganic chemistry Nanotechnology Metallurgy Chemistry Environmental science Optoelectronics Environmental engineering Composite material

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Arsenic contamination and mitigation

Physical Sciences → Environmental Science → Environmental Chemistry

Environmental remediation with nanomaterials

Physical Sciences → Engineering → Biomedical Engineering

Extraction and Separation Processes

Physical Sciences → Engineering → Mechanical Engineering

Cu-Doped Fe@Fe₂O₃ core–shell nanoparticle shifted oxygen reduction pathway for high-efficiency arsenic removal in smelting wastewater

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