废水厌氧处理中溶解性甲烷直接利用研究进展

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Abstract Mainstream anaerobic wastewater treatment processes often produce dissolved methane (CH₄) during operation, which can be released to exacerbate the greenhouse effect and cause energy wastage if not properly treated subsequently. It is important to utilize the dissolved CH₄ produced during the anaerobic biological treatment of wastewater. The direct utilization of dissolved CH₄, unlike removal and recovery, reduces the process of separating CH₄ and has a better potential for net energy production. Generally, dissolved CH₄ could be coupled by anaerobic oxidation of CH₄ with the reduction of other pollutants in the wastewater, including sulfate, nitrate, and heavy metals; or converted it into proteins, biopolymers, methanol, and organic acids with higher commercial value. This review summarized and discussed the three methods of anaerobic methane oxidation, methane-driven microbial fuel cells, and value-added methane conversion, described their advantages and limitations, and summarized their developmental potential to provide ideas for the future development of the utilization of dissolved CH₄ in anaerobic wastewater treatment.

Key words： wastewater anaerobic treatment dissolved methane anaerobic methane oxidation methane-driven value-added conversion of methane

Received: 12 January 2023

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X703.1

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	Articles by authors
	XIAN Yun-chuan
	SU Cheng-yuan
	WANG Zi
	LIU Sheng-tao
	CHEN Zheng-peng
	LIN Xiang-feng
	ZHANG Yun-nan

Cite this article:

XIAN Yun-chuan,SU Cheng-yuan,WANG Zi等. Research progress of direct utilization of dissolved methane in anaerobic biological treatment of wastewater[J]. CHINA ENVIRONMENTAL SCIENCECE, 2023, 43(S1): 79-87.

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http://www.zghjkx.com.cn/EN/ OR http://www.zghjkx.com.cn/EN/Y2023/V43/IS1/79

[1] Stazi V, Tomei M C. Dissolved methane in anaerobic effluents: A review on sustainable strategies for optimization of energy recovery or internal process reuse [J].Journal of Cleaner Production, 2021,317: 128359.
[2] Nusbaum N J. Dairy livestock methane remediation and global warming [J].Journal of Community Health, 2010,35:500-502.
[3] Chang J, Wu Q, Liang P, et al. Enhancement of nitrite-dependent anaerobic methane oxidation via Geobacter sulfurreducens [J].Science of The Total Environment, 2020,766:144230.
[4] 蔡博峰,高庆先,李中华,等.中国城市污水处理厂甲烷排放因子研究[J].中国环境科学, 2015,35(12):118-124. Cai B F, Gao Q X, Li Z H, et al. Estimation of methane emissions of wastewater treatment plants in China [J].China Environmental Science, 2015,35(12):118-124.
[5] Shen L D, Hu B L, Liu S, et al. Anaerobic methane oxidation coupled to nitrite reduction can be a potential methane sink in coastal environments [J].Applied Microbiology and Biotechnology, 2016, 100:7171-7180.
[6] Modin O, Fukushi K, Yamamoto K. Denitrification with methane as external carbon source [J].Water Research, 2007,41:2726-2738.
[7] Ding J, Zeng R J. Fundamentals and potential environmental significance of denitrifying anaerobic methane oxidizing archaea [J].Science of The Total Environment, 2020,757:143928.
[8] Hu S, Zeng R J, Keller J, et al. Effect of nitrate and nitrite on the selection of microorganisms in the denitrifying anaerobic methane oxidation process [J].Environmental Microbiology Reports, 2011,3:315-319.
[9] Kessel M A V, StulTtiens K, Slegers M F, et al. Current perspectives on the application of N-damo and anammox in wastewater treatment [J].Current Opinion in Biotechnology, 2018,50:222-227.
[10] Fca B, Lin L, Song X, et al. Auxiliary voltage enhanced microbial methane oxidation co-driven by nitrite and sulfate reduction -ScienceDirect [J].Chemosphere, 2020,250:126259.
[11] 翟俊,马宏璞,陈忠礼,等.湿地甲烷厌氧氧化的重要性和机制综述[J].中国环境科学, 2017,37(9):3506-3514. Zhai J, Ma H P, Chen Z L, et al. Review on the importance and mechanisms of anaerobic oxidation of methane in wetlands [J].China Environmental Science, 2017,37(9):3506-3514.
[12] Raghoebarsing A A, Pol A, Pas-schoonen K, et al. A microbial consortium couples anaerobic methane oxidation to denitrification [J].Nature, 2006,440:918-921.
[13] Haroon M F, Hu S H, Shi Y, et al. Anaerobic oxidation of methane coupled to nitrate reduction in a novel archaeal lineage [J].Nature, 2013,501:567-570.
[14] Ettwig K F, Alen T V, Pas-schoonen K, et al. Enrichment and molecular detection of denitrifying methanotrophic bacteria of the NC10phylum [J].Applied and Environmental Microbiology, 2009,75: 3656-3662.
[15] Beal E J, House C H, Orphan V J. Manganese-and iron-dependent marine methane oxidation [J].Science, 2009,325:184-187.
[16] Liu T, Li J, Lim Z K, et al. Simultaneous removal of dissolved methane and nitrogen from synthetic mainstream anaerobic effluent [J].Environmental Science & Technology, 2020,54:7629-7638.
[17] Luesken F A, Sanchez J, Van alen T A, et al. Simultaneous nitrite-dependent anaerobic methane and ammonium oxidation processes [J].Applied and Environmental Microbiology, 2011,77:6802-6807.
[18] Islas S, Thalasso F, Gomez J. Evidence of anoxic methane oxidation coupled to denitrification [J].Water Research, 2004,38:13-16.
[19] Ettwig K F, Butler M K, Le Paslier D, et al. Nitrite-driven anaerobic methane oxidation by oxygenic bacteria [J].Nature, 2010,464:543-548.
[20] Timmers P H A, Welte C U, Koehorst J J, et al. Reverse methanogenesis and respiration in methanotrophic archaea [J].Archaea-an International Microbiological Journal, 2017,2017:1654237.
[21] Ettwig K F, Zhu B, Speth D, et al. Archaea catalyze iron-dependent anaerobic oxidation of methane [J].Proceedings of the National Academy of Sciences, 2016,113:12792-12796.
[22] Reimann J, Jetten M S M, Keltjens J T. Metal enzymes in "impossible" microorganisms catalyzing the anaerobic oxidation of ammonium and methane [J].Metal Ions in Life Sciences, 2015,15:257-313.
[23] Meraz J L, Dubrawski K L, Elabbadi S H, et al. Membrane and fluid contactors for safe and efficient methane delivery in methanotrophic bioreactors [J].Journal of Environmental Engineering, 2020,146: 03120006.
[24] Van Kessel M, Stultiens K, Slegers M F W, et al. Current perspectives on the application of N-damo and anammox in wastewater treatment [J].Current Opinion in Biotechnology, 2018,50:222-227.
[25] Sliekers A O, Third K A, Abma W, et al. CANON and Anammox in a gas-lift reactor [J].Fems Microbiology Letters, 2003,218:339-344.
[26] Winkler M K H, Ettwig K F, Vannecke T P W, et al. Modelling simultaneous anaerobic methane and ammonium removal in a granular sludge reactor [J].Water Research, 2015,73:323-331.
[27] FAN S Q, Xie G J, Xing D F et al. Granular sludge coupling nitrate/nitrite dependent anaerobic methane oxidation with Anammox: from proof-of-concept to high rate nitrogen removal [J].Environmental Science & Technology, 2019,54:297-305.
[28] Peng L, Nie W B, Ding J, et al. A mechanistic model for denitrifying anaerobic methane oxidation coupled to dissimilatory nitrate reduction to ammonium [J].Chemosphere, 2021,287:132148.
[29] Zhao Q, Ji M, Li R, et al. Long-term performance of sediment microbial fuel cells with multiple anodes [J].Bioresource Technology, 2017,237:178-185.
[30] Zhong D J, Liao X R, Liu Y Q, et al. Quick start-up and performance of microbial fuel cell enhanced with a polydiallyldimethylammonium chloride modified carbon felt anode [J].Biosensors & Bioelectronics, 2018,119:70-78.
[31] Ding Z W, Lu Y Z, Fu L, et al. Simultaneous enrichment of denitrifying anaerobic methane-oxidizing microorganisms and anammox bacteria in a hollow-fiber membrane biofilm reactor [J].Applied Microbiology & Biotechnology, 2017,101(1):437-446.
[32] Bai Y N, Zhang F, Yu L P, et al. Acetate and electricity generation from methane in conductive fiber membrane-microbial fuel cells [J].Science of the Total Environment, 2022,804:150147.
[33] Zhang K, Wu X L, Chen J, et al. The role and related microbial processes of Mn-dependent anaerobic methane oxidation in reducing methane emissions from constructed wetland-microbial fuel cell [J].Journal of Environmental Management, 2021,294:112935.
[34] Scheller S, Yu H, Chadwick G L, et al. Artificial electron acceptors decouple archaeal methane oxidation from sulfate reduction [J].Science, 2016,351:703-707.
[35] Mcanulty M J, Poosarla V G, Kim K Y, et al. Electricity from methane by reversing methanogenesis [J].Nature Communications, 2017,8: 15419.
[36] Logan B E, Wallack M J, Kim K Y, et al. Assessment of microbial fuel cell configurations and power densities [J].Environmental Science & Technology Letters, 2015,2:206-214.
[37] Li X S, Lee H S, Wang Z W, et al. State-of-the-art management technologies of dissolved methane in anaerobically-treated low-strength wastewaters: A review [J].Water Research, 2021,200:117269.
[38] Dai K, Sun T, Yan Y, et al. Electricity production and microbial community in psychrophilic microbial fuel cells at 10℃ [J].Bioresource Technology, 2020,313:123680.
[39] Xu Z C, Chen S Y, Guo S Y, et al. New insights in light-assisted microbial fuel cells for wastewater treatment and power generation: A win-win cooperation [J].Journal of Power Sources, 2021,501:230000.
[40] Bolognesi S, Cecconet D, Callegari A, et al. Combined microalgal photobioreactor/microbial fuel cell system: Performance analysis under different process conditions [J].Environmental Research, 2021, 192:110263.
[41] Capodaglio A G, Molognoni D, Dallago E, et al. Microbial fuel cells for direct electrical energy recovery from urban wastewaters [J].Scientific World Journal, 2013,634738.
[42] Cuellar M C, Straathof A J J. Downstream of the bioreactor: advancements in recovering fuels and commodity chemicals [J].Current Opinion in Biotechnology, 2020,62:189-195.
[43] Su Y C, Sathyamoorthy S, Chandran K. Bioaugmented methanol production using ammonia oxidizing bacteria in a continuous flow process [J].Bioresource Technology, 2019,279:101-107.
[44] Kalyuzhnaya M G, Puri A W, Lidstrom M E. Metabolic engineering in methanotrophic bacteria [J].Metabolic Engineering, 2015,29:142-152.
[45] Taher E, Chandran K. High-rate, high-yield production of methanol by ammonia-oxidizing bacteria [J].Environmental Science & Technology, 2013,47:3167-3173.
[46] Gupta V, Goei R. Managing dissolved methane gas in anaerobic effluents using microbial resource management-based strategies [J].Bioresource Technology, 2019,289:121601.
[47] Ahmed R, Hamid A K, Krebsbach S A, et al. Critical review of microplastics removal from the environment [J].Chemosphere, 2022, 293:133557.
[48] Singh A K, Srivastava J K, Chandel A K, et al. Biomedical applications of microbially engineered polyhydroxyalkanoates: an insight into recent advances, bottlenecks, and solutions [J].Applied Microbiology and Biotechnology, 2019,103:2007-2032.
[49] Levett I, Birkett G, Davies N, et al. Techno-economic assessment of poly-3-hydroxybutyrate (PHB) production from methane-the case for thermophilic bioprocessing [J].Journal of Environmental Chemical Engineering, 2016,4:3724-3733.
[50] Kavitha G, Rengasamy R, Inbakandan D. Polyhydroxybutyrate production from marine source and its application [J].International Journal of Biological Macromolecules, 2018,111:102-108.