Electrooxidative Degradation of an Anthraquinone Dye with in-situ Electrogenerated Active Chlorine in a Divided Flow Cell

• REACTION KINETICS, CATALYSIS AND…… • Previous Articles Next Articles

Electrooxidative Degradation of an Anthraquinone Dye with in-situ Electrogenerated Active Chlorine in a Divided Flow Cell

YANGYunzhe^a,b;YANGWeishen^a;YANGFenglin^a; ZHANGXingwen^a

^a School of Environmental ＆ Biological Science ＆ Technology, Dalian University of Technology, Dalian 116024,China
^b School of Science, Shenyang University of Technology, Shenyang 110024, China

Received:1900-01-01 Revised:1900-01-01 Online:2005-10-28 Published:2005-10-28
Contact: YANG Yunzhe

在不分隔的反应器中原位电生成活性氯氧化降解蒽醌染料

杨蕴哲^a,b;杨卫身^a;杨凤林^a;张兴文^a

^a School of Environmental ＆ Biological Science ＆ Technology, Dalian University of Technology, Dalian 116024,China
^b School of Science, Shenyang University of Technology, Shenyang 110024, China

通讯作者: 杨蕴哲

Abstract

Abstract: The purpose of this paper was to investigate the possibility of treating C. I. Reactive Blue 19 wastewater by electrochemical oxidation via electrogenerated active chlorine, using metallic oxide coatings （dimensional stable anode, DSA） as anode. The electrolysis for the simulated wastewater was condducted at a constant current. Absorbances at 592 nm and 255 nm were measured to follow the decolorization of the dye and the degradatin of its aromaticring. After 4 h of electrolysis under the experimental conditions： current density of 15 A·m^-2, 0.2 mol·L^-1 NaCl, 0.1 mol·L^-1 Na2SO4, 0.1 mmol·L^-1 dye, initial pH=6.4 and T=30℃, 100% decolorization of the dye and about 45% degradation of its aromatic ring were achieved, while no obvious changge of total organic carbon was observed. The experimental results suggest that the decolorization of the dye and degradation of its aromatic ring were directly affected by current density, temperature, concentrations of the dye and sodium chloride, while slightly affected by initial pH and sodium sulfate concentration; the decolorization of the dye and degradation of its aromatic ring followed pseudo-first-order kinetics; and indirect electrooxidation, using electrogenerated active chlorine, predominated in the electrochemical oxidation.

Key words: electrochemical oxidation, anthraquinone dye, electrogenerated active chlorine, galvanostatic model, flow cell

摘要： The purpose of this paper was to investigate the possibility of treating C. I. Reactive Blue 19 wastewater by electrochemical oxidation via electrogenerated active chlorine, using metallic oxide coatings （dimensional stable anode, DSA） as anode. The electrolysis for the simulated wastewater was condducted at a constant current. Absorbances at 592 nm and 255 nm were measured to follow the decolorization of the dye and the degradatin of its aromaticring. After 4 h of electrolysis under the experimental conditions： current density of 15 A·m^-2, 0.2 mol·L^-1 NaCl, 0.1 mol·L^-1 Na2SO4, 0.1 mmol·L^-1 dye, initial pH=6.4 and T=30℃, 100% decolorization of the dye and about 45% degradation of its aromatic ring were achieved, while no obvious changge of total organic carbon was observed. The experimental results suggest that the decolorization of the dye and degradation of its aromatic ring were directly affected by current density, temperature, concentrations of the dye and sodium chloride, while slightly affected by initial pH and sodium sulfate concentration; the decolorization of the dye and degradation of its aromatic ring followed pseudo-first-order kinetics; and indirect electrooxidation, using electrogenerated active chlorine, predominated in the electrochemical oxidation.

关键词: 反应器;原位电生成活性氯;氧化降解;蒽醌染料;电气化学氧化

YANGYunzhe,YANGWeishen,YANGFenglin, ZHANGXingwen. Electrooxidative Degradation of an Anthraquinone Dye with in-situ Electrogenerated Active Chlorine in a Divided Flow Cell[J]. .

杨蕴哲,杨卫身,杨凤林,张兴文. 在不分隔的反应器中原位电生成活性氯氧化降解蒽醌染料 [J]. CIESC Journal.

[1]	Yuxin REN, Runfeng XU, Wanying WANG, Pengzhong CHEN, Xiaojun PENG. Synthesis and stability study of anthraquinone dyes for color photoresist [J]. CIESC Journal, 2022, 73(5): 2251-2261.
[2]	Yinhao ZHANG, Fei ZHAN, Chengxu LI, Chang YU, Jieshan QIU. Concentration flow cells with ammonium vanadium bronze electrodes for harvesting salinity gradient energy [J]. CIESC Journal, 2022, 73(2): 857-864.
[3]	YE Zhiping, ZHOU Danfei, LIU Zifeng, ZHOU Qingqing, WANG Jiade. Electro-oxidation information of p-toluene sulfonic acid on Ti/PbO₂electrode [J]. CIESC Journal, 2021, 72(5): 2810-2816.
[4]	ZHANG Tingting,LIU Yongjun,ZHOU Chengtao,DONG Xin,LIU Jiachen. TiO₂-SnO₂ coated bamboo biochar for electrochemical treatment of coking wastewater [J]. CIESC Journal, 2020, 71(12): 5793-5801.
[5]	Jiade WANG, Tongbin YUAN, Danfei ZHOU, Xule ZHOU, Yongping GAN. Mechanism of phenol electro-oxidation in aqueous solution based on in situ infrared spectroscopy [J]. CIESC Journal, 2019, 70(12): 4821-4827.
[6]	ZHU Ruizhi, ZHOU Yang, XIA Tiantian, LIU Zhihua, WANG Kunmiao, CHANG Gang, CAI Zhiwei, CAO Ribing, HE Yunbin. Facile preparation of Pd/graphite nanoplate composites for electrocatalytic oxidation of methanol [J]. CIESC Journal, 2017, 68(11): 4398-4406.
[7]	WANG Xiaojuan, WU Beilei, MA Chun'an. Electrochemical oxidation characteristics of zinc O,O,O’,O’-tetrabutyl bis(phosphorodithioate)on glassy carbon electrode [J]. CIESC Journal, 2013, 64(7): 2550-2555.
[8]	CHEN Bo, QUAN Xuejun, CHENG Zhiliang, ZHU Xincai, ZHANG Shuhan. Electrochemical oxidation of biologically treated leachate from municipal solid waste incineration plant [J]. CIESC Journal, 2013, 64(4): 1396-1402.
[9]	CHENG Zihong1，GAO Zhanxian1，XU Jun1，WANG Ren1，MA Wei1，HAN Diqiu2. Glucose，starch，and phenol electrochemical oxidation coupled with hydrogen production [J]. Chemical Industry and Engineering Progree, 2013, 32(07): 1542-1546.
[10]	HONG Xiaping, ZHANG Rong, TONG Shaoping, MA Chun’an. Preparation of Ti/PTFE-F-PbO₂ Electrode with a Long Life from the Sulfamic Acid Bath and Its Application in Organic Degradation [J]. , 2011, 19(6): 1033-1038.