[1] ADAK A., MANGALGIRI K. P., LEE J., et al. UV irradiation and UV-H2O2 advanced oxidation of the roxarsone and nitarsone organoarsenicals. Water Research, 2015, 70: 74-85
[2] SINGH R., SINGH S., PARIHAR P., et al. Arsenic contamination, consequences and remediation techniques: A review. Ecotoxicology and Environmental Safety, 2015, 112: 247-270
[3] JIANG Bo, Guo Jianbo, Wang Zhaohui, et al. A green approach towards simultaneous remediations of chromium (VI) and arsenic (III) in aqueous solution. Chemical Engineering Journal, 2015, 262: 1144-1151
[4] 严群, 桂勇刚, 周娜娜, 等. 混凝沉淀法处理含砷选矿废水. 环境工程学报, 2014, 8(9): 3683-3688 YAN Qun, GUI Yonggang, ZHOU Na'na, et al. Treatment of arsenic-containing mineral processing wastewater by coagulation and sedimentation process. Chinese Journal of Environmental Engineering, 2014, 8(9): 3683-3688(in Chinese)
[5] 谢冬梅, 曹林洪, 崔金立. 二氧化钛颗粒制备及其对水中三价砷的去除. 环境工程学报, 2013, 7(4): 1279-1284 XIE Dongmei, CAO Linhong, CUI Jinli. Preparation and evaluation of TiO2 granule for As (III) removal from water. Chinese Journal of Environmental Engineering, 2013, 7(4): 1279-1284(in Chinese)
[6] SHI Lin, WANG Wei, YUAN Shoujun, et al. Electrochemical stimulation of microbial roxarsone degradation under anaerobic conditions. Environmental Science & Technology, 2014, 48(14): 7951-7958
[7] ZHU Xiangdong, WANG Yujun, LIU Cun, et al. Kinetics, intermediates and acute toxicity of arsanilic acid photolysis. Chemosphere, 2014, 107: 274-281
[8] CZAPLICKA M., BRATEK Ł., Jaworek K., et al. Photo-oxidation of p-arsanilic acid in acidic solutions: Kinetics and the identification of by-products and reaction pathways. Chemical Engineering Journal, 2014, 243: 364-371
[9] HUANG Lianxi, YAO Lixiao, HE Zhaohuan, et al. Roxarsone and its metabolites in chicken manure significantly enhance the uptake of As species by vegetables. Chemosphere, 2014, 100: 57-62
[10] GARBARINO J. R., BEDNAR A. J., RUTHERFORD D. W., et al. Environmental fate of roxarsone in poultry litter. I. Degradation of roxarsone during composting. Environmental Science & Technology, 2003, 37(8): 1509-1514
[11] JUNG B. K., JUN J. W., HASAN Z., et al. Adsorptive removal of p-arsanilic acid from water using mesoporous zeolitic imidazolate framework-8. Chemical Engineering Journal, 2015, 267: 9-15
[12] ZHENG Shan, JIANG Wenjun, CAI Yong, et al. Adsorption and photocatalytic degradation of aromatic organoarsenic compounds in TiO2suspension. Catalysis Today, 2014, 224: 83-88
[13] JIANG Bo, ZHENG Jingtang, QIU Shi, et al. Review on electrical discharge plasma technology for wastewater remediation. Chemical Engineering Journal, 2014, 236: 348-368
[14] DHAR R. K., ZHENG Y., RUBENSTONE J., et al. A rapid colorimetric method for measuring arsenic concentrations in groundwater. Analytica Chimica Acta, 2004, 526(2): 203-209
[15] LIU Renlan, GUO Yaoguang, WANG Zhaohui, et al. Iron species in layered clay: Efficient electron shuttles for simultaneous conversion of dyes and Cr (VI). Chemosphere, 2014, 95: 643-646
[16] EISENBERG G. Colorimetric determination of hydrogen peroxide. Industrial and Engineering Chemistry Analytical Edition, 1943, 15(5): 327-328
[17] ISHIBASHI K. I., FUJISHIMA A., WATANABE T., et al. Detection of active oxidative species in TiO2 photocatalysis using the fluorescence technique. Electrochemistry Communications, 2000, 2(3): 207-210
[18] LIU Yongjun. Simultaneous oxidation of phenol and reduction of Cr (VI) induced by contact glow discharge electrolysis. Journal of Hazardous Materials, 2009, 168(2/3): 992-996
[19] XU Tielian, CAI Yong, O'SHEA K. E. Adsorption and photocatalyzed oxidation of methylated arsenic species in TiO2 suspensions. Environmental Science & Technology, 2007, 41(15): 5471-5477
[20] JIANG Bo, HU Ping, ZHENG Xing, et al. Rapid oxidation and immobilization of arsenic by contact glow discharge plasma in acidic solution. Chemosphere, 2015, 125: 220-226
[21] XU Tielian, KAMAT P. V., JOSHI S., et al. Hydroxyl radical mediated degradation of phenylarsonic acid. The Journal of Physical Chemistry A, 2007, 111(32): 7819-7824