Arsenite oxidation and removal driven by a bio-electro-Fenton process under neutral pH conditions

文献类型: 外文期刊

第一作者: Wang, Xiang-Qin

作者: Wang, Xiang-Qin;Liu, Chuan-Ping;Yuan, Yong;Li, Fang-bai

作者机构:

关键词: Microbial fuel cell;Bio-electro-Fenton process;γ-FeOOH;Arsenic;Oxidation

期刊名称:JOURNAL OF HAZARDOUS MATERIALS ( 影响因子:10.588; 五年影响因子:10.129 )

ISSN:

年卷期:

页码:

收录情况: SCI

摘要: The iron-catalyzed oxidation of arsenite (As(Ⅲ)) associated with Fenton or Fenton-like reactions is one of the most efficient arsenic removal methods. However, the conventional chemical or electro-Fenton systems for the oxidation of As(Ⅲ) are only efficient under acid conditions. In the present study, a cost-effective and efficient bio-electro-Fenton process was performed for As(Ⅲ) oxidation in a dual-chamber microbial fuel cell (MFC) under neutral pH conditions. In such a system, the Fenton reagents, including H_2O_2 and Fe(Ⅱ), were generated in situ by microbial-driven electro-reduction of O_2 and γ-FeOOH, respectively, without an electricity supply. The results indicated that the process was capable of inducing As(Ⅲ) oxidation with an apparent As(Ⅲ) depletion first-order rate constant of 0.208 h~(-1). The apparent oxidation current efficiency was calculated to be as high as 73.1%. The γ-FeOOH dosage in the cathode was an important factor in determining the system performance. Fourier-transform infrared spectroscopy (FT-IR) analysis indicated that As(Ⅴ) was bound to the solid surface as a surface complex but not as a precipitated solid phase. The mechanism of bio-E-Fenton reaction for As(Ⅲ) oxidation was also proposed. The bio-electro-Fenton system makes it potentially attractive method for the detoxification of As(Ⅲ) from aqueous solution.

分类号: TB1

  • 相关文献

[1]Naturally derived carbon nanofibers as sustainable electrocatalysts for microbial energy harvesting: A new application of spider silk. Zhou, Lihua,Fu, Peng,Cai, Xixi,Zhou, Shungui,Yuan, Yong.

[2]Glycerol Stabilized NaBH4 Reduction for Preparation Carbon Supported Pt-Ni Alloy Nanoparticles Used as Oxygen-Reduction Electrocatalysts for Microbial Fuel Cells. Wang, Zhong,Wang, Min,Zhao, Jinsheng,Wang, Zhong,Yan, Zhenhua. 2015

[3]Bio-current as an indicator for biogenic Fe(II) generation driven by dissimilatory iron reducing bacteria. Li, Fangbai,Feng, Chunhua,Yue, Xianjun,Wei, Chaohai.

[4]A polypyrrole/anthraquinone-2,6-disulphonic disodium salt (PPy/AQDS)-modified anode to improve performance of microbial fuel cells. Feng, Chunhua,Ma, Le,Mai, Hongjian,Lang, Xuemei,Fan, Shuanshi,Li, Fangbai.

[5]Honeycomb-like hierarchical carbon derived from livestock sewage sludge as oxygen reduction reaction catalysts in microbial fuel cells. Deng, Lifang,Yuan, Haoran,Ruan, Yingying,Chen, Yong,Cai, Xixi,Zhou, Shungui,Yuan, Yong,Deng, Lifang,Yuan, Haoran,Ruan, Yingying.

[6]A Simple Method of Improving Microbial Fuel-Cell Performance Based on Polyaniline/Carbon Composite Anodes. Yuan, Yong,Kim, Sunghyun.

[7]Wiring microbial biofilms to the electrode by osmium redox polymer for the performance enhancement of microbial fuel cells. Yuan, Yong,Shin, Hyosul,Kang, Chan,Kim, Sunghyun.

[8]Microbial fuel cell with an azo-dye-feeding cathode. Liu, Liang,Li, Fang-bai,Liu, Liang,Feng, Chun-hua,Li, Xiang-zhong,Liu, Liang.

[9]In-situ Cr(VI) reduction with electrogenerated hydrogen peroxide driven by iron-reducing bacteria. Liu, Liang,Yuan, Yong,Li, Fang-bai,Liu, Liang,Feng, Chun-hua,Liu, Liang.

[10]Understanding the role of Fe(III)/Fe(II) couple in mediating reductive transformation of 2-nitrophenol in microbial fuel cells. Li, Fangbai,Liu, Liang,Tong, Hui,Feng, Chunhua,Feng, Chunhua,Liu, Yongye,Yue, Xianjun,Sun, Kewen.

[11]Electricity generation from starch processing wastewater using microbial fuel cell technology. Lu, Na,Zhang, Jin-tao,Ni, Jin-ren,Lu, Na,Zhou, Shun-gui,Zhang, Jin-tao.

[12]The oxidative transformation of sodium arsenite at the interface of alpha-MnO2 and water. Li, Xiu-juan,Liu, Cheng-shuai,Li, Fang-bai,Zhang, Li-jia,Liu, Chuan-ping,Li, Xiu-juan,Zhou, Yong-zhang,Li, Yong-tao,Zhang, Li-jia,Li, Xiu-juan. 2010

[13]Enhancement of tolerance of Indian mustard (Brassica juncea) to mercury by carbon monoxide. Meng, De Kun,Yang, Zhi Min,Chen, Jian. 2011

[14]Oxidation of elemental sulfur in paddy soils as influenced by flooded condition and plant growth in pot experiment. Zhou, W,Wan, M,He, P,Li, ST,Lin, B. 2002

[15]Relationship between oxidative degradation of 2-mercaptobenzothiazole and physicochemical properties of manganese (hydro)oxides. Liu, C. S.,Zhang, L. J.,Wu, C. A.,Li, F. B.,Feng, C. H.,Liu, C. S.,Li, X. Z.. 2009

[16]Mono-oxidation of alpha-aroyl ketene dithioacetals with hydrogen peroxide: an unexpected stereoselectivity. Yu, CY,Wang, LB,Huang, ZT,Hsu, ACT. 1997

[17]Oxidation of (-)-epicatechin is a precursor of litchi pericarp enzymatic browning. Liu, Liang,Xu, Yujuan,Zhang, Mingwei,Xiao, Gengsheng,Cao, Shaoqian,Deng, Qianchun.

[18]Effects of Oxidation on Water Distribution and Physicochemical Properties of Porcine Myofibrillar Protein Gel. Li, Yin,Li, Xia,Wang, Jin-zhi,Zhang, Chun-hui,Sun, Hong-mei,Wang, Chun-qing,Xie, Xiao-lei. 2014

[19]Expression of CYP107Z13 in Streptomyces lividans TK54 catalyzes the oxidation of avermectin to 4aEuro(3)-oxo-avermectin. Liu, Weide,Ji, Ying,Niu, Jing,Li, Mei. 2012

[20]Effects of acute and chronic heat stress on plasma metabolites, hormones and oxidant status in restrictedly fed broiler breeders. Xie, Jingjing,Tang, Li,Lu, Lin,Zhang, Liyang,Luo, Xugang,Tang, Li,Lin, Xi,Liu, Hsiao-Ching,Odle, Jack.

作者其他论文 更多>>

微信小程序