Electrochemical oxidation of humic acid at the antimony- and nickel-doped tin oxide electrode

Chengli TANG , Wei YAN , Chunli ZHENG

Front. Environ. Sci. Eng. ›› 2014, Vol. 8 ›› Issue (3) : 337 -344.

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Front. Environ. Sci. Eng. ›› 2014, Vol. 8 ›› Issue (3) : 337 -344. DOI: 10.1007/s11783-013-0545-9
RESEARCH ARTICLE
RESEARCH ARTICLE

Electrochemical oxidation of humic acid at the antimony- and nickel-doped tin oxide electrode

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Abstract

This work investigated the degradation of humic acid (HA) in aqueous solution by electrochemical oxidation with Antimony- and Nickel-doped Tin oxide electrode (Ni-Sb-SnO2/Ti electrode) as the anode. Initial concentrations of HA ranged from 3 to 9 mg·L-1. Under such a concentration scope, the degradation of HA was a mass transfer controlled process. Degradation rate increased with the increase of HA initial concentration. Test on the effect of tert-butanol revealed that ·OH played an important role in the oxidation of HA. The absence of cation Ca2+ was beneficial to HA degradation, which suggested that both indirect and direct electrolyze happened during the whole electrochemical oxidation process. Alkaly (pH= 12) and neutral (pH= 7) conditions were benefical to HA degradation.

Keywords

electrochemical oxidation / humic acid (HA) / natural water / Ni-Sb-SnO2/Ti electrode

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Chengli TANG, Wei YAN, Chunli ZHENG. Electrochemical oxidation of humic acid at the antimony- and nickel-doped tin oxide electrode. Front. Environ. Sci. Eng., 2014, 8(3): 337-344 DOI:10.1007/s11783-013-0545-9

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References

Publishing order | Descend order by publishing year | Descend order by cited within
[1]

Aeschbacher M, Sander M, Schwarzenbach R P. Novel electrochemical approach to assess the redox properties of humic substances. Environmental Science & Technology, 2010, 44(1): 87–93
[2]

Aeschbacher M, Brunner S H, Schwarzenbach R P, Sander M. Assessing the effect of humic acid redox state on organic pollutant sorption by combined electrochemical reduction and sorption experiments. Environmental Science & Technology, 2012, 46(7): 3882–3890
[3]

Li X Z, Fan C M, Sun Y P. Enhancement of photocatalytic oxidation of humic acid in TiO2 suspensions by increasing cation strength. Chemosphere, 2002, 48(4): 453–460
[4]

Uyguner C S, Bekbolet M. A comparative study on the photocatalytic degradation of humic substances of various origins. Desalination, 2005, 176(1–3): 167–176
[5]

Shin H S, Lim K H. Spectroscopic and elemental investigation of microbial decomposition of aquatic fulvic acid in biological process of drinking water treatment. Biodegradation, 1996, 7(4): 287–295
[6]

Chen G H, Hung Y T. Electrochemical wastewater treatment processess. In: Wang L K, Hung Y T, Shammas N K, eds. Handbook of Environmental Engineering. Totowa: The Humana Press Incorporated, 2007, 57–60
[7]

Steinmann P, Shotyk W. Ion chromatography of organic-rich natural waters from peatlands V. Fe2+ and Fe3+. Journal of Chromatography A, 1995, 706(1–2): 293–299
[8]

Voelker B M, Morel F M M, Sulzberger B. Iron redox cycling in surface waters: effects of humic substances and light. Environmental Science & Technology, 1997, 31(4): 1004–1011
[9]

Coates J D, Ellis D J, Blunt-Harris E L, Gaw C V, Roden E E, Lovley D R. Recovery of humic-reducing bacteria from a diversity of environments. Applied and Environmental Microbiology, 1998, 64(4): 1504–1509
[10]

Lovley D R, Fraga J L, Blunt-Harris E L, Hayes L A, Phillips E J P, Coates J D. Humic substances as a mediator for microbially catalyzed metal reduction. Acta Hydrochimica et Hydrobiologica, 1998, 26(3): 152–157
[11]

Ma J, Graham N J D. Degradation of atrazine by manganese catalysed ozonation: influence of humic substances. Water Research, 1999, 33(3): 785–793
[12]

Schulten H R, Schnitzer M. A state of the art structural concept for humic substances. Naturwissenschaften, 1993, 80(1): 29–30
[13]

Chen D Q, Zhang D M, Wei Z P. Study on photocatalytic degradation of humic acid by Ag deposited TiO2. Journal of Anhui Agricultural Sciences, 2010, 38(17): 9379–9381 (in Chinese)
[14]

Ding G Y, Li C X, Wang Y F, Fan C M, Sun Y P. Study on the photocatalytic oxidation of humic acid in the water by ferric oxide under visible-light. Applied Chemical Industry, 2009, 38(6): 788–791 (in Chinese)
[15]

Pan L M, Ji M, Wang X D, Zhao L J, Lu B. Kinetics of humic acid degradation by TiO2 nanotubes/UV/O3. Journal of the Chemical Industry and Engineering Society of China, 2009, 60(9): 2215–2220 (in Chinese)
[16]

Zhou Y, Huang K L, Zhu Z P, Yang B, Qiu H Y, Gu Y, Liu T. Preparation of Gd/N-codoped nano-TiO2 and degradation of humic acid. Journal of Central South University, 2008, 39(4): 677–681 (in Chinese)
[17]

Jiang Y L, Jiang Z H, Liu H L. Study on adsorption of humic acid from aqueous solution on B2O3·TiO2/Ti film. Journal of Chemical Engineering of Chinese Universities, 2007, 21(6): 954–958 (in Chinese)
[18]

Motheo A J, Pinhedo L. Electrochemical degradation of humic acid. The Science of the Total Environment, 2000, 256(1): 67–76
[19]

Bekbolet M, Uyguner C S, Selcuk H, Rizzo L, Nikolaou A D, Meric S, Belgiorno V. Application of oxidative removal of NOM to drinking water and formation of disinfection by-products. Desalination, 2005, 176(1–3): 155–166
[20]

Scialdone O, Guarisco C, Galia A, Filardo G, Silvestri G, Amatore C, Sella C, Thouin L. Anodic abatement of organic pollutants in water in micro reactors. Journal of Electroanalytical Chemistry, 2010, 638(2): 293–296
[21]

Scialdone O. Electrochemical oxidation of organic pollutants in water at metal oxide electrodes: A simple theoretical model including direct and indirect oxidation processes at the anodic surface. Electrochimica Acta, 2009, 54(26): 6140–6147
[22]

Wang Y H, Cheng S A, Chan K Y, Li X Y. Electrolytic generation of ozone on antimony- and nickel-doped tin oxide electrode. Journal of the Electrochemical Society, 2005, 152(11): D197–D200
[23]

Wei S Q, Liu Y, Wang S Q. Electrochemical treatment of humic acid in water. Contemporary Chemical Industry, 2004, 33(6): 350–353 (in Chinese)
[24]

Panizza M, Cerisola G. Electrochemical oxidation as a final treatment of synthetic tannery wastewater. Environmental Science & Technology, 2004, 38(20): 5470–5475
[25]

Radha K V, Sridevi V, Kalaivani K. Electrochemical oxidation for the treatment of textile industry wastewater. Bioresource Technology, 2009, 100(2): 987–990
[26]

Deligiorgis A, Xekoukoulotakis N P, Diamadopoulos E, Mantzavinos D. Electrochemical oxidation of table olive processing wastewater over boron-doped diamond electrodes: treatment optimization by factorial design. Water Research, 2008, 42(4–5): 1229–1237
[27]

Wang B, Chang X, Ma H. Electrochemical oxidation of refractory organics in the coking wastewater and chemical oxygen demand (COD) removal under extremely mild conditions. Industrial & Engineering Chemistry Research, 2008, 47(21): 8478–8483
[28]

Li L, Liu Y. Ammonia removal in electrochemical oxidation: mechanism and pseudo-kinetics. Journal of Hazardous Materials, 2009, 161(2–3): 1010–1016
[29]

Scialdone O, Galia A, Gurreri L, Randazzo S. Electrochemical abatement of chloroethanes in water: reduction, oxidation and combined processes. Electrochimica ActA, 2010, 55(3): 701–708
[30]

Faouzi A M, Nasr B, Abdellatif G. Electrochemical degradation of anthraquinone dye Alizarin Red S by anodic oxidation on boron-doped diamond. Dyes and Pigments, 2007, 73(1): 86–89
[31]

Oliveira R T S, Salazar-Banda G R, Santos M C, Calegaro M L, Miwa D W, Machado S A S, Avaca L A. Electrochemical oxidation of benzene on boron-doped diamond electrodes. Chemosphere, 2007, 66(11): 2152–2158
[32]

Rodgers J D, Jedral W, Bunce N I. Electrochemical oxidation of chlorinated phenols. Environmental Science & Technology, 1999, 33(9): 1453–1457
[33]

Vidotti M, de Torresi S I C, Kubota L T. Cordoba de Torresi, Susana I.; Kubota, Lauro T. Electrochemical oxidation of glycine by doped nickel hydroxide modified electrode. Sensors and Actuators B, Chemical, 2008, 135(1): 245–249
[34]

Martinez-Huitle C A, Ferro S. Electrochemical oxidation of organic pollutants for the wastewater treatment: direct and indirect processes. Chemical Society Reviews, 2006, 35(12): 1324–1340
[35]

Stevic M C, Ignjatovic L M, Ciric-Marjanovic G, Stanisic S M, Stankovic D M, Zima J. Voltammetric behaviour and determination of 8-Hydroxyquinoline using a Glassy Carbon Paste Electrode and the theoretical study of its electrochemical oxidation mechanism. International Journal of Electrochemical Science, 2011, 6(7): 2509–2525
[36]

Kinumoto T, Toyoda M, Choo H S, Nose M, Iriyama Y, Abe T, Ogumi Z. Electrochemical oxidation mechanism of highly oriented pyrolytic graphite in sulfuric acid solution. ECS Transactions, 2008, 13(17): 111–118
[37]

Li L, Liu Y. Ammonia removal in electrochemical oxidation: mechanism and pseudo-kinetics. Journal of Hazardous Materials, 2009, 161(2–3): 1010–1016
[38]

Silva A P, Carvalho A F, Maia G. Use of electrochemical techniques to characterize methamidophos and humic acid specifically adsorbed onto Pt and PtO films. Journal of Hazardous Materials, 2011, 186(1): 645–650

[39]

Dietz R N, Pruzansk J, Smith J D.Effect of pH on stoichiometry of iodimetric determination of ozone. Analytical Chemistry, 1973, 45(2): 402–404
[40]

Ding H Y, Feng Y J, Liu J F. Preparation and properties of Ti/SnO2–Sb2O5 electrodes by electrodeposition. Materials Letters, 2007, 61(27): 4920–4923
[41]

Grimm J, Bessarabov D, Maier W, Storck S, Sanderson R D. Sol-gel film-preparation of novel electrodes for the electrocatalytic oxidation of organic pollutants in water. Desalination, 1998, 115(3): 295–302
[42]

Scialdone O, Galia A, Guarisco C, Randazzo S, Filardo G. Electrochemical incineration of oxalic acid at boron doped diamond anodes-Role of operative parameters. Electrochimica Acta, 2008, 53(5): 2095–2108
[43]

Zeng K M, Dong H S, Shi J F. Mechanism of removing dissolved humic acids from drinking water by multi-electrodes of granular activated carbon. Journal of Sichuan University (Engineering Science Edition), 2001, 33(6): 45–49 (in Chinese)
[44]

Jeong J, Kim C, Yoon J. The effect of electrode material on the generation of oxidants and microbial inactivation in the electrochemical disinfection processes. Water Research, 2009, 43(4): 895–901
[45]

Scialdone O, Galia A, Filardo G. Electrochemical incineration of 1, 2-dichloroethane: effect of the electrode material. Electrochimica Acta, 2008, 53(24): 7220–7225
[46]

Scialdone O, Randazzo S, Galia A, Silvestri G. Electrochemical oxidation of organics in water: role of operative parameters in the absence and in the presence of NaCl. Water Research, 2009, 43(8): 2260–2272

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