Abstract
The ammonia removal performance of a hybrid electrooxidation and adsorption reactor (HEAR) is evaluated. The influences of current density, chloride concentration, and packing particles for ammonia removal in HEAR were investigated, and the performance of HEAR under serials circulation was studied. Results indicated that ammonia removal efficiency achieved around 70 % under the optimal condition after 30-min electrolysis. The optimal condition was determined as current density of 10 mA/cm2, Cl−/NH4 + molar ratio of 1.8, and modified zeolites as particles. The ammonia adsorption kinetic and adsorption isotherm on zeolites fitted well with second-order kinetic and Langmuir isotherm model, respectively. Adsorption amount of ammonia on zeolites sampled at 30-min electrolysis achieved 2.4 mg/L, higher than 1.9 mg/L of zeolites at 20-min electrolysis, indicating that electrooxidation coupled with adsorption led to simultaneous ammonia removal and zeolite regeneration in HEAR. No decrease of ammonia removal efficiency was observed over several cycles with the electrooxidation treatment. The presence of free chlorine indicating ammonia removal in HEAR was due to the combined influence by adsorption and indirect electrooxidation. These results showed that HEAR was a prospective alternative as a tertiary treatment for wastewater with low chloride ions.
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References
Alpat SK, Oezbayrak O, Alpat S, Akcay H (2008) The adsorption kinetics and removal of cationic dye, Toluidine Blue O, from aqueous solution with Turkish zeolite. J Hazard Mater 151:213–220
APHA (1998) Standard methods for the examination of water and wastewater, 20th edn. APHA, USA
Batzias FA, Sidiras DK (2007) Simulation of methylene blue adsorption by salts-treated beech sawdust in batch and fixed-bed systems. J Hazard Mater 149:8–17
Bouaziz I, Chiron C, Abdelhedi R, Savall A, Serrano KG (2014) Treatment of dilute methylene blue-containing wastewater by coupling sawdust adsorption and electrochemical regeneration. Environ Sci Pollut R 21:8565–8572
Cabeza A, Urtiaga AM, Ortiz I (2007) Electrochemical treatment of landfill leachates using a boron-doped diamond anode. Ind Eng Chem Res 46:1439–1446
Cao G, Zhang L, Sheng M, Liu Y (2014) Biological denitrification of groundwater by a composite membrane bioreactor. Adv Mater Res 864-867:2083–2089
Chao Z, Yonghai J, Yunlin L, Zhongxin H, Lei Z, Minghua Z (2013) Three-dimensional electrochemical process for wastewater treatment: a general review. Chem Eng J 228:455–467
Chen Y, Liu C, Nie J, Luo X, Wang D (2013) Chemical precipitation and biosorption treating landfill leachate to remove ammonium-nitrogen. Clean Techn Environ Policy 15:395–399
Cho K, Qu Y, Kwon D, Zhang H, Cid CA, Aryanfar A, Hoffmann MR (2014) Effects of anodic potential and chloride ion on overall reactivity in electrochemical reactors designed for solar-powered wastewater treatment. Environ Sci Technol 48:2377–2384
Diaz V, Ibanez R, Gomez P, Urtiaga AM, Ortiz I (2011) Kinetics of electro-oxidation of ammonia-N, nitrites and COD from a recirculating aquaculture saline water system using BDD anodes. Water Res 45:125–134
Ding J, Zhao QL, Wang K, Hu WY, Li W, Li A, Lee DJ (2014) Ammonia abatement for low-salinity domestic secondary effluent with a hybrid electrooxidation and adsorption reactor. Ind Eng Chem Res 53:9999–10006
Fernandes A, Spranger P, Fonseca AD, Pacheco MJ, Ciriaco L, Lopes A (2014) Effect of electrochemical treatments on the biodegradability of sanitary landfill leachates. Appl Catal B-Environ 144:514–520
Ganesan P, Lakshmi J, Sozhan G, Vasudevan S (2013) Removal of manganese from water by electrocoagulation: adsorption, kinetics and thermodynamic studies. Can J Chem Eng 91:448–458
Gendel Y, Lahav O (2012) Revealing the mechanism of indirect ammonia electrooxidation. Electrochim Acta 63:209–219
Gendel Y, Lahav O (2013) A novel approach for ammonia removal from fresh-water recirculated aquaculture systems, comprising ion exchange and electrochemical regeneration. Aquac Eng 52:27–38
Haaken D, Dittmar T, Schmalz V, Worch E (2014) Disinfection of biologically treated wastewater and prevention of biofouling by UV/electrolysis hybrid technology: influence factors and limits for domestic wastewater reuse. Water Res 52:20–28
He S, Huang Q, Zhang Y, Wang L, Nie Y (2015) Investigation on direct and indirect electrochemical oxidation of ammonia over Ru-Ir/TiO2 Anode. Ind Eng Chem Res 54:1447–1451
Hedstrom A (2001) Ion exchange of ammonium in zeolites: a literature review. J Environ Eng-Asce 127:673–681
Hussain SN, de Las HN, Asghar HMA, Brown NW, Roberts EPL (2014) Disinfection of water by adsorption combined with electrochemical treatment. Water Res 54:170–178
Kamaraj R, Vasudevan S (2015) Decontamination of selenate from aqueous solution by oxidized multi-walled carbon nanotubes. Powder Technol 274:268–275
Kamaraj R, Davidson DJ, Sozhan G, Vasudevan S (2015) Adsorption of herbicide 2-(2,4-dichlorophenoxy) propanoic acid by electrochemically generated aluminum hydroxides: an alternative to chemical dosing. RSC Adv 5:39799–39809
Karadag D, Koc Y, Turan M, Armagan B (2006) Removal of ammonium ion from aqueous solution using natural Turkish clinoptilolite. J Hazard Mater 136:604–609
Kim KW, Kim YJ, Kim IT, Park GI, Lee EH (2006) Electrochemical conversion characteristics of ammonia to nitrogen. Water Res 40:1431–1441
Kong W, Wang B, Ma H, Gu L (2006) Electrochemical treatment of anionic surfactants in synthetic wastewater with three-dimensional electrodes. J Hazard Mater 137:1532–1537
Lakshmi J, Vasudevan S (2013) Graphene—a promising material for removal of perchlorate (ClO4 −) from water. Environ Sci Pollut R 20:5114–5124
Lei X, Li M, Zhang Z, Feng C, Bai W, Sugiura N (2009) Electrochemical regeneration of zeolites and the removal of ammonia. J Hazard Mater 169:746–750
Li L, Liu Y (2009) Ammonia removal in electrochemical oxidation: mechanism and pseudo-kinetics. J Hazard Mater 161:1010–1016
Li M, Feng C, Zhang Z, Lei X, Chen N, Sugiura N (2010) Simultaneous regeneration of zeolites and removal of ammonia using an electrochemical method. Micropor Mesopor Mat 127:161–166
Li L, Fang X, Zhang D, Huang Y (2015) The adsorption and oxidation of ammonia in granular activated carbon packed three-dimensional electrode reactor. Int J Electrochem Sci 10:4083–4089
Lin L, Lei Z, Wang L, Liu X, Zhang Y, Wan C, Lee D, Tay JH (2013) Adsorption mechanisms of high-levels of ammonium onto natural and NaCl-modified zeolites. Sep Purif Technol 103:15–20
Mohammed FM, Roberts EPL, Hill A, Campen AK, Brown NW (2011) Continuous water treatment by adsorption and electrochemical regeneration. Water Res 45:3065–3074
Mook WT, Chakrabarti MH, Aroua MK, Khan G, Ali BS, Islam MS, Abu Hassan MA (2012) Removal of total ammonia nitrogen (TAN), nitrate and total organic carbon (TOC) from aquaculture wastewater using electrochemical technology: a review. Desalination 285:1–13
Nageswara Rao N, Rohit M, Nitin G, Parameswaran PN, Astik JK (2009) Kinetics of electrooxidation of landfill leachate in a three-dimensional carbon bed electrochemical reactor. Chemosphere 76:1206–1212
Panizza M, Cerisola G (2004) Electrochemical oxidation as a final treatment of synthetic tannery wastewater. Environ Sci Technol 38:5470–5475
Pérez G, Saiz J, Ibanez R, Urtiaga AM, Ortiz I (2012) Assessment of the formation of inorganic oxidation by-products during the electrocatalytic treatment of ammonium from landfill leachates. Water Res 46:2579–2590
Pernet-Coudrier B, Qi W, Liu H, Mueller B, Berg M (2012) Sources and pathways of nutrients in the semi-arid region of beijing Tianjin, china. Environ Sci Technol 46:5294–5301
Sirés I, Brillas E, Oturan MA, Rodrigo MA, Panizza M (2014) Electrochemical advanced oxidation processes: today and tomorrow. A review. Environ Sci Pollut R 21:8336–8367
Szpyrkowicz L, Naumczyk J, Ziliograndi F (1995) Electrochemical treatment of tanny wastewater using Ti/Pt and Ti/Pt/Ir electrodes. Water Res 29:517–524
Turro E, Giannis A, Cossu R, Gidarakos E, Mantzavinos D, Katsaounis A (2011) Electrochemical oxidation of stabilized landfill leachate on DSA electrodes. J Hazard Mater 190:460–465
Vanlangendonck Y, Corbisier D, Van Lierde A (2005) Influence of operating conditions on the ammonia electro-oxidation rate in wastewaters from power plants (ELONITA (TM) technique). Water Res 39:3028–3034
Vasudevan S, Lakshmi J (2012) The adsorption of phosphate by graphene from aqueous solution. RSC Adv 2:5234–5242
Wang L, Fu J, Qiao Q, Zhao Y (2007) Kinetic modeling of electrochemical degradation of phenol in a three-dimension electrode process. J Hazard Mater 144:118–125
Wang C, Huang Y, Zhao Q, Ji M (2014) Treatment of secondary effluent using a three-dimensional electrode system: COD removal, biotoxicity assessment, and disinfection effects. Chem Eng J 243:1–6
Wijesekara R, Nomura N, Matsumura M (2005) Electrochemical removal of ammonia, chemical oxygen demand and energy consumption from aquaculture waters containing different marine algal species. J Chem Technol Biot 80:1408–1415
Yusof AM, Keat LK, Ibrahim Z, Majid ZA, Nizam NA (2010) Kinetic and equilibrium studies of the removal of ammonium ions from aqueous solution by rice husk ash-synthesized zeolite Y and powdered and granulated forms of mordenite. J Hazard Mater 174:380–385
Zhao H, Sun Y, Xu L, Ni J (2010) Removal of acid orange 7 in simulated wastewater using a three-dimensional electrode reactor: removal mechanisms and dye degradation pathway. Chemosphere 78:46–51
Zhu X, Ni J, Xing X, Li H, Jiang Y (2011) Synergies between electrochemical oxidation and activated carbon adsorption in three-dimensional boron-doped diamond anode system. Electrochim Acta 56:1270–1274
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The authors wish to express their gratitude to the financial support from Project 51121062 (National Creative Research Groups) provided by National Nature Science Foundation of China, the National Critical Scientific and Technological Project of Water Pollution Control and Management (2012ZX07201003-002), and Project ES201417 from State Key Laboratory of Urban Water Resource and Environment, Harbin Institute of Technology.
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Ding, J., Zhao, QL., Zhang, J. et al. Hybrid electrooxidation and adsorption process for the removal of ammonia in low concentration chloride wastewater. Environ Sci Pollut Res 24, 5098–5105 (2017). https://doi.org/10.1007/s11356-015-5793-8
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DOI: https://doi.org/10.1007/s11356-015-5793-8