Abstract
In this study, microbial fuel cells (MFCs) were explored to promote the nitrogen removal performance of combined anaerobic ammonium oxidation (anammox) and Fe-C micro-electrolysis (CAE) systems. The average total nitrogen (TN) removal efficiency of the modified MFC system was 85.00%, while that of the anammox system was 62.16%. Additionally, the effective operation time of this system increased from six (CAE system alone) to over 50 days, significantly promoting TN removal. The enhanced performance could be attributed to the electron transferred from the anode to the cathode, which aided in reducing nitrate/nitrite in denitrification. The H+ released through the proton exchange membrane caused a decrease in the pH, facilitating Fe corrosion. The pyrolyzed waste tire used as the cathode could immobilize microorganisms, enhance electron transport, and produce a natural Fe-C micro-electrolysis system. According to the microbial community analysis, Candidatus kuenenia was the major genus involved in the anammox process. Furthermore, the SM1A02 genus exhibited the highest abundance and was enriched the fastest, and could be a novel potential strain that aids the anammox process.
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References
Ao L, Xia F, Ren Y, Xu J, Shi D, Zhang S, Gu L, He Q (2019). Enhanced nitrate removal by micro-electrolysis using Fe0 and surfactant modified activated carbon. Chemical Engineering Journal, 357: 180–187
APHA (2005). Standard Methods for the Examination of Water and Wastewater, 21th ed. Washington, DC: American Public Health Association, Water Environment Federation
Bhadra S, De P P, Mondal N, Mukhapadhyaya R, Das Gupta S (2003). Regeneration of carbon black from waste automobile tires. Journal of Applied Polymer Science, 89(2): 465–473
Chamchoi N, Nitisoravut S, Schmidt J E (2008). Inactivation of ANAMMOX communities under concurrent operation of anaerobic ammonium oxidation (ANAMMOX) and denitrification. Bioresource Technology, 99(9): 3331–3336
Chen W, Feng H, Shen D, Jia Y, Li N, Ying X, Chen T, Zhou Y, Guo J, Zhou M (2018). Carbon materials derived from waste tires as highperformance anodes in microbial fuel cells. Science of the Total Environment, 618: 804–809
Clauwaert P, Rabaey K, Aelterman P, De Schamphelaire L, Pham T H, Boeckx P, Boon N, Verstraete W (2007). Biological denitrification in microbial fuel cells. Environmental Science & Technology, 41(9): 3354–3360
de Toledo R A, Hin Chao U, Shen T, Lu Q, Li X, Shim H (2019). Development of hybrid processes for the removal of volatile organic compounds, plasticizer, and pharmaceutically active compound using sewage sludge, waste scrap tires, and wood chips as sorbents and microbial immobilization matrices. Environmental Science and Pollution Research International, 26(12): 11591–11604
Deng S, Li D, Yang X, Xing W, Li J, Zhang Q (2016). Biological denitrification process based on the Fe0-carbon micro-electrolysis for simultaneous ammonia and nitrate removal from low organic carbon water under a microaerobic condition. Bioresource Technology, 219: 677–686
Ding B, Li Z, Qin Y (2017). Nitrogen loss from anaerobic ammonium oxidation coupled to Iron(III) reduction in a riparian zone. Environmental Pollution, 231: 379–386
Du R, Peng Y, Cao S, Wu C, Weng D, Wang S, He J (2014). Advanced nitrogen removal with simultaneous Anammox and denitrification in sequencing batch reactor. Bioresource Technology, 162: 316–322
Gao D, Wang X, Liang H, Wei Q, Dou Y, Li L (2018). Anaerobic ammonia oxidizing bacteria: Ecological distribution, metabolism, and microbial interactions. Frontiers of Environmental Science & Engineering, 12(3): 10
Huang B, Fu G, He C, He H, Yu C, Pan X (2019). Ferroferric oxide loads humic acid doped anode accelerate electron transfer process in anodic chamber of bioelectrochemical system. Journal of Electroanalytical Chemistry, 851: 113464
Han Z, Miao Y, Dong J, Shen Z, Zhou Y, Liu S, Yang C (2019). Enhanced nitrogen removal and microbial analysis in partially saturated constructed wetland for treating anaerobically digested swine wastewater. Frontiers of Environmental Science & Engineering, 13(4): 52
Jin X, Guo F, Ma W, Liu Y, Liu Hong (2019). Heterotrophic anodic denitrification improves carbon removal and electricity recovery efficiency in microbial fuel cells. Chemical Engineering Journal, 370: 527–535
Kanaparthi D, Conrad R (2015). Role of humic substances in promoting autotrophic growth in nitrate-dependent iron-oxidizing bacteria. Systematic and Applied Microbiology, 38(3): 184–188
Lai B, Zhou Y, Yang P, Yang J, Wang J (2013). Degradation of 3,3′-iminobis-propanenitrile in aqueous solution by Fe0/GAC micro-electrolysis system. Chemosphere, 90(4): 1470–1477
Li C, Ren H, Xu M, Cao J (2015). Study on anaerobic ammonium oxidation process coupled with denitrification microbial fuel cells (MFCs) and its microbial community analysis. Bioresource Technology, 175: 545–552
Li X, Yuan Y, Huang Y, Liu H W, Bi Z, Yuan Y, Yang P B (2018). A novel method of simultaneous NH4+ and NO3− removal using Fe cycling as a catalyst: Feammox coupled with NAFO. Science of the Total Environment, 631–632: 153–157
Liu M, Huang Y, Liu Q, Hu X, Liu Q, Chen H, Dong Y, Zhao Y, Niu S (2019). Ferric oxide as a support of carbide slag for effective transesterification of triglycerides in soybean oil. Energy Conversion and Management, 198: 111785
Lu Q, de Toledo R A, Xie F, Li J, Shim H (2015). Combined removal of a BTEX, TCE, and cis-DCE mixture using Pseudomonas sp. immobilized on scrap tyres. Environmental Science and Pollution Research International, 22(18): 14043–14049
Lu Q, de Toledo R A, Xie F, Li J, Shim H (2017). Reutilization of waste scrap tyre as the immobilization matrix for the enhanced bioremoval of a monoaromatic hydrocarbons, methyl tert-butyl ether, and chlorinated ethenes mixture from water. Science of the Total Environment, 583: 88–96
Lv Y, Chen X, Wang L, Ju K, Chen X, Miao R, Wang X (2016). Microprofiles of activated sludge aggregates using microelectrodes in completely autotrophic nitrogen removal over nitrite (CANON) reactor. Frontiers of Environmental Science & Engineering, 10(2): 390–398
Lv Y, Wang Y, Shan M, Shen X, Su Y (2011). Denitrification of coking wastewater with micro-electrolysis. Journal of Environmental Sciences-China, 23: S128–S131
Lyu L, Zhang K, Li Z, Ma Y, Chai T, Pan Y, Wang X, Li S, Zhu T (2019). Inhibition of anammox activity by phenol: Suppression effect, community analysis and mechanism simulation. International Biodeterioration & Biodegradation, 141: 30–38
Ma B, Qian W, Yuan C, Yuan Z, Peng Y (2017). Achieving mainstream nitrogen removal through coupling anammox with denitratation. Environmental Science & Technology, 51(15): 8405–8413
Ma B, Wang S, Cao S, Miao Y, Jia F, Du R, Peng Y (2016). Biological nitrogen removal from sewage via anammox: Recent advances. Bioresource Technology, 200: 981–990
Mao Y, Xia Y, Zhang T (2013). Characterization of Thauera-dominated hydrogen-oxidizing autotrophic denitrifying microbial communities by using high-throughput sequencing. Bioresource Technology, 128: 703–710
Martínez J D, Puy N, Murillo R, Garcia T, Navarro M V, Mastral A M (2013). Waste tyre pyrolysis: A review. Renewable & Sustainable Energy Reviews, 23: 179–213
Naga Samrat M V V, Kesava Rao K, Ruggeri B, Tommasi T (2018). Denitrification of water in a microbial fuel cell (MFC) using seawater bacteria. Journal of Cleaner Production, 178: 449–456
Park H I, Choi Y J, Pak D (2005). Autohydrogenotrophic denitrifying microbial community in a glass beads biofilm reactor. Biotechnology Letters, 27(13): 949–953
Qiao S, Yin X, Zhou J, Wei L E, Zhong J (2018). Integrating anammox with the autotrophic denitrification process via electrochemistry technology. Chemosphere, 195: 817–824
Schaedler F, Kappler A, Schmidt C (2018). A revised iron extraction protocol for environmental samples rich in nitrite and carbonate. Geomicrobiology Journal, 35(1): 23–30
Strous M, Heijnen J J, Kuenen J G, Jetten M S M (1998). The sequencing batch reactor as a powerful tool for the study of slowly growing anaerobic ammonium-oxidizing microorganisms. Applied Microbiology and Biotechnology, 50(5): 589–596
Tang C J, Zheng P, Wang C H, Mahmood Q (2010). Suppression of anaerobic ammonium oxidizers under high organic content in high-rate Anammox UASB reactor. Bioresource Technology, 101(6): 1762–1768
Thomas B S, Gupta R C (2016). A comprehensive review on the applications of waste tire rubber in cement concrete. Renewable & Sustainable Energy Reviews, 54: 1323–1333
Tian S, Tian Z, Yang H, Yang M Y, Zhang Y (2017). Detection of viable bacteria during sludge ozonation by the combination of ATP assay with PMA-Miseq sequencing. Water (Basel), 9(3): 1–12
Tomaszewski M, Cema G, Ziembińska-Buczyńska A (2017). Significance of pH control in anammox process performance at low temperature. Chemosphere, 185: 439–444
Xie F, Ma X, Zhao B, Cui Y, Zhang X, Yue X (2020). Promoting the nitrogen removal of anammox process by Fe-C micro-electrolysis. Bioresource Technology, 297: 122429
Xing W, Li D, Li J, Hu Q, Deng S (2016). Nitrate removal and microbial analysis by combined micro-electrolysis and autotrophic denitrification. Bioresource Technology, 211: 240–247
Xu F, Cao F Q, Kong Q, Zhou L L, Yuan Q, Zhu Y J, Wang Q, Du Y D, Wang Z D (2018). Electricity production and evolution of microbial community in the constructed wetland-microbial fuel cell. Chemical Engineering Journal, 339: 479–486
Xu F, Ouyang D L, Rene E R, Ng H Y, Guo L L, Zhu Y J, Zhou L L, Yuan Q, Miao M S, Wang Q, Kong Q (2019). Electricity production enhancement in a constructed wetland-microbial fuel cell system for treating saline wastewater. Bioresource Technology, 288: 121462
Yang Q, Peng Y, Liu X, Zeng W, Mino T, Satoh H (2007). Nitrogen removal via nitrite from municipal wastewater at low temperatures using real-time control to optimize nitrifying communities. Environmental Science & Technology, 41(23): 8159–8164
Yilmaz P, Yarza P, Rapp J, Glöckner F (2016). Expanding the world of marine bacterial and archaeal clades. Frontiers in Microbiology, 6: 1–29
Zhang J, Zhang Y, Li Y, Zhang L, Qiao S, Yang F, Quan X (2012). Enhancement of nitrogen removal in a novel anammox reactor packed with Fe electrode. Bioresource Technology, 114: 102–108
Zhou A, Liu W, Varrone C, Wang Y, Wang A, Yue X (2015). Evaluation of surfactants on waste activated sludge fermentation by pyrosequencing analysis. Bioresource Technology, 192: 835–840
Zhu G, Chen G, Yu R, Li H, Wang C (2016). Enhanced simultaneous nitrification/denitrification in the biocathode of a microbial fuel cell fed with cyanobacteria solution. Process Biochemistry, 51(1): 80–88
Zhu G, Wang S, Ma B, Wang X, Zhou J, Zhao S, Liu R (2018). Anammox granular sludge in low-ammonium sewage treatment: Not bigger size driving better performance. Water Research, 142: 147–158
Acknowledgements
This research was supported by the Scientific and Technological Project of Shanxi Province (Nos. 201903D321057 and 201903D321055), by the National Natural Science Foundation of China (Grant Nos. 51708386 and 21501129), by the China Postdoctoral Science Foundation (No. 2016M601290), and the Ministry of Environmental Protection of China (Major Science and Technology Program, Nos. 2019YFC0408601 and 2019YFC0408602).
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Highlights
• MFC promoted the nitrogen removal of anammox with Fe-C micro-electrolysis.
• Reutilize pyrolysis waste tire as micro-electrolysis and electrode materials.
• Total nitrogen removal efficiency of modified MFC increased to 85.00%.
• Candidatus kuenenia and SM1A02 were major genera responsible for nitrogen removal.
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Xie, F., Zhao, B., Cui, Y. et al. Reutilize tire in microbial fuel cell for enhancing the nitrogen removal of the anammox process coupled with iron-carbon micro-electrolysis. Front. Environ. Sci. Eng. 15, 121 (2021). https://doi.org/10.1007/s11783-021-1409-3
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DOI: https://doi.org/10.1007/s11783-021-1409-3