A large amount of real complex wastewaters are generated every year, which leads to a great environmental burden. Various treatment technologies were deployed to remove the contaminants in the wastewaters. However, these actual wastewaters have not been sufficiently treated due to their complex properties, high-concentration organics, incomplete utilization of hard-biodegradable substrates, the high energy input required, etc. Recently, microbial electrolysis cells (MECs), a great potential technology, has emerged for various wastewater treatment, because not only do they demonstrate satisfactory performance during wastewater treatment, but they also generate renewable H2 as a clean energy carrier. Unlike previous reviews, this review introduced the characteristics of every complicated wastewater, and focused on analyzing and summarizing MEC development for wastewater treatment. The performances of MECs were systematically reviewed in terms of organics removal, H2 production, Columbic efficiency, and energy efficiency. MEC performances for treating actual complex wastewaters and producing H2 can be optimized through operation parameters, electrode materials, catalyst materials, etc. In addition, the challenges and opportunities including complexity of wastewaters, instability of H2 production, robust microorganisms, effect of membrane on two-chamber MEC, and integration of MEC with other treatment processes were deeply discussed. Except for the technical feasibility, both environmental feasibility and economic feasibility also need to meet social requirements. This review can indeed provide a basis for high-efficiency treatment and practical commercial applications of recalcitrant wastewaters via MECs in the future.
Keywords: microbial electrolysis cells, complex wastewater, H2 production, renewable energy, energy efficiency
DOI: 10.25165/j.ijabe.20191205.5061

Citation: Shen R X, Zhao L X, Lu J W, Watson J, Si B C, Chen X, et al. Treatment of recalcitrant wastewater and hydrogen production via microbial electrolysis cells. Int J Agric & Biol Eng, 2019; 12(5): 179–189.

microbial electrolysis cells, complex wastewater, H2 production, renewable energy, energy efficiency

Pandey P, Shinde V N, Deopurkar R L, Kale S P, Patil S A, Pant D. Recent advances in the use of different substrates in microbial fuel cells toward wastewater treatment and simultaneous energy recovery. Applied Energy, 2016; 168: 706–723.

Qureshi A S, Hussain M I, Ismail S, Khan Q M. Evaluating heavy metal accumulation and potential health risks in vegetables irrigated with treated wastewater. Chemosphere, 2016; 163: 54–61.

Zeppilli M, Simoni M, Paiano P, Majone M. Two-side cathode microbial electrolysis cell for nutrients recovery and biogas upgrading. Chemical Engineering Journal, 2019.

Gan K, Mou X, Xu Y, Wang H. Application of ozonated piggery wastewater for cultivation of oil-rich Chlorella pyrenoidosa. Bioresource Technology, 2014; 171: 285–290.

Iskander S M, Brazil B, Novak J T, He Z. Resource recovery from landfill leachate using bioelectrochemical systems: Opportunities, challenges, and perspectives. Bioresource Technology, 2016; 201: 347–354.

Katuri K P, Ali M, Saikaly P E. The role of microbial electrolysis cell in urban wastewater treatment: integration options, challenges, and prospects. Current Opinion in Biotechnology, 2019(57): 101–110.

Ghosh S, Dairkee U K, Chowdhury R, Bhattacharya P. Hydrogen from food processing wastes via photofermentation using purple non-sulfur bacteria (PNSB): A review. Energy Conversion and Management, 2016.

Ivanov I, Ren L, Siegert M, Logan B E. A quantitative method to evaluate microbial electrolysis cell effectiveness for energy recovery and wastewater treatment. International Journal of Hydrogen Energy, 2013; 38(30): 13135–13142.

Lusk B G, Colin A, Parameswaran P, Rittmann B E, Torres C I. Simultaneous fermentation of cellulose and current production with an enriched mixed culture of thermophilic bacteria in a microbial electrolysis cell. Microbial Biotechnology, 2018; 11(1): 63–73.

Ullery M L, Logan B E. Anode acclimation methods and their impact on microbial electrolysis cells treating fermentation effluent. International Journal of Hydrogen Energy, 2015; 40(21): 6782–6791.

Jayabalan T, Matheswaran M, Naina Mohammed S. Biohydrogen production from sugar industry effluents using nickel based electrode materials in microbial electrolysis cell. International Journal of Hydrogen Energy, 2019; 44(32): 17381–17388.

Khan M Z, Nizami A S, Rehan M, Ouda O K M, Sultana S, Ismail I M, et al. Microbial electrolysis cells for hydrogen production and urban wastewater treatment: A case study of Saudi Arabia. Applied Energy, 2017; 185: 410–420.

Guo X, Liu J, Xiao B. Bioelectrochemical enhancement of hydrogen and methane production from the anaerobic digestion of sewage sludge in single-chamber membrane-free microbial electrolysis cells. International Journal of Hydrogen Energy, 2013; 38(3): 1342–1347.

Jwa E, Yun Y, Kim H, Jeong N, Park S, Nam J. Domestic wastewater treatment in a tubular microbial electrolysis cell with a membrane electrode assembly. International Journal of Hydrogen Energy, 2019; 44(2): 652–660.

Mahmoud M, Parameswaran P, Torres C I, Rittmann B E. Relieving the fermentation inhibition enables high electron recovery from landfill leachate in a microbial electrolysis cell. RSC Adv., 2016; 6(8): 6658–6664.

Ye Y, Logan B E. The importance of OH− transport through anion exchange membrane in microbial electrolysis cells. International Journal of Hydrogen Energy, 2018; 43(5): 2645–2653.

Brown R K, Harnisch F, Wirth S, Wahlandt H, Dockhorn T, Dichtl N, et al. Evaluating the effects of scaling up on the performance of bioelectrochemical systems using a technical scale microbial electrolysis cell. Bioresource Technology, 2014; 163: 206–213.

Hua T, Li S, Li F, Zhou Q, Ondon B S. Microbial electrolysis cell as an emerging versatile technology: a review on its potential application, advance and challenge. Journal of Chemical Technology & Biotechnology, 2019; 94(6): 1697–1711.

Kadier A, Kalil M S, Chandrasekhar K, Mohanakrishna G, Saratale G D, Saratale R G, et al. Surpassing the current limitations of h igh purity H2 production in microbial electrolysis cell (MECs): Strategies for inhibiting growth of methanogens. Bioelectrochemistry, 2017.

Rathinam N K, Bibra M, Salem D R, Sani R K. Thermophiles for biohydrogen production in microbial electrolytic cells. Bioresource Technology, 2019.

Park S, Rhee C, Shin S G, Shin J, Mohamed H O, Choi Y, et al. Methanogenesis stimulation and inhibition for the production of different target electrobiofuels in microbial electrolysis cells through an on-demand control strategy using the coenzyme M and 2-bromoethanesulfonate. Environment International, 2019; 131: 105006.

Rozenfeld S, Ouaknin Hirsch L, Gandu B, Farber R, Schechter A, Cahan R. Improvement of microbial electrolysis cell activity by using anode based on combined plasma-pretreated carbon cloth and stainless steel. Energies, 2019; 12(10): 1968.

Ren L, Siegert M, Ivanov I, Pisciotta J M, Logan B E. Treatability studies on different refinery wastewater samples using high-throughput microbial electrolysis cells (MECs). Bioresource Technology, 2013; 136(1): 322–328.

Heidrich E S, Edwards S R, Dolfing J, Cotterill S E, Curtis T P. Performance of a pilot scale microbial electrolysis cell fed on domestic wastewater at ambient temperatures for a 12 month period. Bioresource Technology, 2014; 173(1): 87–95.

Kuntke P, Sleutels T H J A, Saakes M, Buisman C J N. Hydrogen production and ammonium recovery from urine by a microbial electrolysis cell. International Journal of Hydrogen Energy, 2014; 39(10): 4771–4778.

Jia Y H, Choi J Y, Ryu J H, Kim C H, Lee W K, Tran H T, et al. Hydrogen production from wastewater using a microbial electrolysis cell. Korean Journal of Chemical Engineering, 2010; 27(6): 1854–1859.

Kargi F, Catalkaya E C, Uzuncar S. Hydrogen gas production from waste anaerobic sludge by electrohydrolysis: Effects of applied DC voltage. International Journal of Hydrogen Energy, 2011; 36(3): 2049–2056.

Lu L, Hou D, Fang Y, Huang Y, Ren Z J. Nickel based catalysts for highly efficient H2 evolution from wastewater in microbial electrolysis cells. Electrochimica Acta, 2016; 206: 381–387.

Escapa A, Lobato A, A D M G, N A M. Hydrogen production and COD elimination rate in a continuous microbial electrolysis cell: the influence of hydraulic retention time and applied voltage. Environmental Progress & Sustainable Energy, 2013; 32(2): 263–268.

Liu H, Hu H, Chignell J, Fan Y. Microbial electrolysis: novel technology for hydrogen production from biomass. Biofuels, 2010; 1(1): 129–142.

Heidrich E S, Dolfing J, Scott K, Edwards S R, Jones C, Curtis T P. Production of hydrogen from domestic wastewater in a pilot-scale microbial electrolysis cell. Applied Microbiology and Biotechnology, 2013; 97(15): 6979–6989.

Yahya A M, Hussain M A, Abdul Wahab A K. Modeling, optimization, and control of microbial electrolysis cells in a fed-batch reactor for production of renewable biohydrogen gas. International Journal of Energy Research, 2015; 39(4): 557–572.

Jafary T, Daud W R W, Ghasemi M, Kim B H, Carmona-Martínez A A, Bakar M H A, et al. A comprehensive study on development of a biocathode for cleaner production of hydrogen in a microbial electrolysis cell. Journal of Cleaner Production, 2017; 164: 1135–1144.

Zou S, Qin M, Moreau Y, He Z. Nutrient-energy-water recovery from synthetic sidestream centrate using a microbial electrolysis cell - forward osmosis hybrid system. Journal of Cleaner Production, 2017; 154: 16–25.

Pepè Sciarria T, Vacca G, Tambone F, Trombino L, Adani F. Nutrient recovery and energy production from digestate using microbial electrochemical technologies (METs). Journal of Cleaner Production, 2019; 208: 1022–1029.

Jafary T, Daud W R W, Ghasemi M, Kim B H, Bakar M H A, Jahim J M, et al. Assessment of recirculation batch mode of operation in bioelectrochemical system; a way forward for cleaner production of energy and waste treatment. Journal of Cleaner Production, 2017; 142: 2544–2555.

Jiang Y, Zeng R J. Bidirectional extracellular electron transfers of electrode-biofilm: Mechanism and application. Bioresource Technology, 2019; 271: 439–448.

Wrana N, Sparling R, Cicek N, Levin D B. Hydrogen gas production in a microbial electrolysis cell by electrohydrogenesis. Journal of Cleaner Production, 2010; 18: S105–S111.

Yavuz Y, Koparal A S, öğütveren Ü B. Treatment of petroleum refinery wastewater by electrochemical methods. Desalination, 2010; 258(1-3): 201–205.

Shen R, Liu Z, He Y, Zhang Y, Lu J, Zhu Z, et al. Microbial electrolysis cell to treat hydrothermal liquefied wastewater from cornstalk and recover hydrogen: Degradation of organic compounds and characterization of microbial community. International Journal of Hydrogen Energy, 2016; 41(7): 4132–4142.

Lewis A J, Ren S, Ye X, Kim P, Labbe N, Borole A P. Hydrogen production from switchgrass via an integrated pyrolysis-microbial electrolysis process. Bioresource Technology, 2015; 195: 231–241.

Brooks V, Lewis A J, Dulin P, Beegle J R, Rodriguez M, Borole A P. Hydrogen production from pine-derived catalytic pyrolysis aqueous phase via microbial electrolysis. Biomass and Bioenergy, 2018; 119: 1–9.

Lewis A J, Borole A P. Understanding the impact of flow rate and recycle on the conversion of a complex biorefinery stream using a flow-through microbial electrolysis cell. Biochemical Engineering Journal, 2016; 116: 95–104.

Chen H, Wan J, Chen K, Luo G, Fan J, Clark J, et al. Biogas production from hydrothermal liquefaction wastewater (HTLWW): Focusing on the microbial communities as revealed by high-throughput sequencing of full-length 16S rRNA genes. Water Research, 2016; 106: 98–107.

Pham M, Schideman L, Scott J, Rajagopalan N, Plewa M J. Chemical and biological characterization of wastewater generated from hydrothermal liquefaction of Spirulina. Environmental Science & Technology, 2013; 47(4): 2131–2138.

Panisko E, Wietsma T, Lemmon T, Albrecht K, Howe D. Characterization of the aqueous fractions from hydrotreatment and hydrothermal liquefaction of lignocellulosic feedstocks. Biomass and Bioenergy, 2015; 74: 162–171.

Yu G, Zhang Y, Schideman L, Funk T, Wang Z. Distributions of carbon and nitrogen in the products from hydrothermal liquefaction of low-lipid microalgae. Energy & Environmental Science, 2011; 4: 4587–4595.

Zheng M, Schideman L C, Tommaso G, Chen W, Zhou Y, Nair K, et al. Anaerobic digestion of wastewater generated from the hydrothermal liquefaction of Spirulina: Toxicity assessment and minimization. Energy Conversion and Management, 2017; 141: 420–428.

Lu J, Li H, Zhang Y, Liu Z. Nitrogen migration and transformation during hydrothermal liquefaction of livestock manures. ACS Sustainable Chemistry & Engineering, 2018; 6(10): 13570–13578.

Lu J, Zhang J, Zhu Z, Zhang Y, Zhao Y, Li R, et al. Simultaneous production of biocrude oil and recovery of nutrients and metals from human feces via hydrothermal liquefaction. Energy Conversion and Management, 2017; 134: 340–346.

Ruirui L, Xia R, Na D, Zhang Y, Zhidan L, Haifeng L. Application of zeolite adsorption and biological anaerobic digestion technology on hydrothermal liquefaction wastewater. I Int J Agric & Biol Eng, 2017; 10(1): 163–168.

Si B, Li J, Zhu Z, Shen M, Lu J, Duan N, et al. Inhibitors degradation and microbial response during continuous anaerobic conversion of hydrothermal liquefaction wastewater. Science of The Total Environment, 2018; 630: 1124–1132.

Si B, Yang L, Zhou X, Watson J, Tommaso G, Chen W, et al. Anaerobic conversion of hydrothermal liquefaction aqueous: Fate of organics and intensification with granule activated carbon/ozone pretreatment. Green Chemistry, 2018.

Zeng X, Borole A P, Pavlostathis S G. Biotransformation of furanic and phenolic compounds with hydrogen gas production in a microbial electrolysis cell. Environmental Science & Technology, 2015; 49(22): 13667–13675.

Shen R, Lu J, Zhu Z, Duan N, Lu H, Zhang Y, et al. Effects of organic strength on performance of microbial electrolysis cell fed with hydrothermal liquefied wastewater. Int J Agric & Biol Eng, 2017; 10(3): 206–217.

Ahmed I N, Yang X, Dubale A A, Shao R, Guan R, Meng X, et al. Zirconium based metal-organic framework in-situ assisted hydrothermal pretreatment and enzymatic hydrolysis of Platanus X acerifolia exfoliating bark for bioethanol production. Bioresource Technology, 2019; 280: 213–221.

Dimos K, Paschos T, Louloudi A, Kalogiannis K G, Lappas A A, Papayannakos N, et al. Effect of various pretreatment methods on bioethanol production from cotton stalks. Fermentation, 2019; 5(1): 5.

Thomsen M H, Thygesen A, Thomsen A B. Hydrothermal treatment of wheat straw at pilot plant scale using a three-step reactor system aiming at high hemicellulose recovery, high cellulose digestibility and low lignin hydrolysis. Bioresource Technology, 2008; 99(10): 4221–4228.

Thygesen A, Marzorati M, Boon N, Thomsen A B, Verstraete W. Upgrading of straw hydrolysate for production of hydrogen and phenols in a microbial electrolysis cell (MEC). Applied Microbiology and Biotechnology, 2011; 89(3): 855–865.

Zeng X, Borole A P, Pavlostathis S G. Inhibitory effect of furanic and phenolic compounds on exoelectrogenesis in a microbial electrolysis cell bioanode. Environmental Science & Technology, 2016; 50(20): 11357–11365.

Zeng X, Borole A P, Pavlostathis S G. Performance evaluation of a continuous-flow bioanode microbial electrolysis cell fed with furanic and phenolic compounds. Royal Society of Chemistry, 2016; 6: 65563–65571.

Zeng X, Collins M A, Borole A P, Pavlostathis S G. The extent of fermentative transformation of phenolic compounds in the bioanode controls exoelectrogenic activity in a microbial electrolysis cell. Water Research, 2017; 109: 299–309.

Iskander S M, Brazil B, Novak J T, He Z. Resource recovery from landfill leachate using bioelectrochemical systems: Opportunities, challenges, and perspectives. Bioresource Technology, 2016; 201: 347–354.

Zhang G, Jiao Y, Lee D. A lab-scale anoxic/oxic-bioelectrochemical reactor for leachate treatments. Bioresource Technology, 2015; 186: 97–105.

Mahmoud M, Parameswaran P, Torres C I, Rittmann B E. Fermentation pre-treatment of landfill leachate for enhanced electron recovery in a microbial electrolysis cell. Bioresource Technology, 2014; 151: 151–158.

Mahmoud M, Parameswaran P, Torres C I, Rittmann B E. Fermentation pre-treatment of landfill leachate for enhanced electron recovery in a microbial electrolysis cell. Bioresource Technology, 2014; 151: 151–158.

Hassan M, Fernandez A S, San Martin I, Xie B, Moran A. Hydrogen evolution in microbial electrolysis cells treating landfill leachate: Dynamics of anodic biofilm. International Journal of Hydrogen Energy, 2018; 43(29): 13051–13063.

Wagner R C, Regan J M, Oh S, Zuo Y, Logan B E. Hydrogen and methane production from swine wastewater using microbial electrolysis cells. Water Research, 2009; 43(5): 1480–1488.

Kiely P D, Cusick R, Call D F, Selembo P A, Regan J M, Logan B E. Anode microbial communities produced by changing from microbial fuel cell to microbial electrolysis cell operation using two different wastewaters. Bioresource Technology, 2011; 102(1): 388–394.

Ibekwe A M, Murinda S E, Debroy C, Reddy G B. Potential pathogens, antimicrobial patterns and genotypic diversity of Escherichia coliisolates in constructed wetlands treating swine wastewater. FEMS Microbiology Ecology, 2016; 92(2): 1–14.

Yang D, Deng L, Zheng D, Wang L, Liu Y. Separation of swine wastewater into different concentration fractions and its contribution to combined anaerobic-aerobic process. Journal of Environmental Management, 2016; 168: 87–93.

Ma D, Jiang Z, Lay C, Zhou D. Electricity generation from swine wastewater in microbial fuel cell: Hydraulic reaction time effect. International Journal of Hydrogen Energy, 2016; 41(46): 21820–21826.

Zamora P, Georgieva T, Ter Heijne A, Sleutels T H J A, Jeremiasse A W, Saakes M, et al. Ammonia recovery from urine in a scaled-up Microbial Electrolysis Cell. Journal of Power Sources, 2017; 356: 491–499.

Oh S, Logan B E. Hydrogen and electricity production from a food processing wastewater using fermentation and microbial fuel cell technologies. Water Research, 2005; 39(19): 4673–4682.

Tenca A, Cusick R D, Schievano A, Oberti R, Logan B E. Evaluation of low cost cathode materials for treatment of industrial and food processing wastewater using microbial electrolysis cells. International Journal of Hydrogen Energy, 2013; 38(4): 1859–1865.

Cusick R D, Bryan B, Parker D S, Merrill M D, Mehanna M, Kiely P D, et al. Performance of a pilot-scale continuous flow microbial electrolysis cell fed winery wastewater. Applied Microbiology and Biotechnology, 2011; 89(6): 2053–2063.

Moreno R, Escapa A, Cara J, Carracedo B, Gómez X. A two-stage process for hydrogen production from cheese whey: Integration of dark fermentation and biocatalyzed electrolysis. International Journal of Hydrogen Energy, 2015; 40(1): 168–175.

Wang Y, Guo W, Xing D, Chang J, Ren N. Hydrogen production using biocathode single-chamber microbial electrolysis cells fed by molasses wastewater at low temperature. International Journal of Hydrogen Energy, 2014; 39(33): 19369–19375.

Sangeetha T, Guo Z, Liu W, Cui M, Yang C, Wang L, et al. Cathode material as an influencing factor on beer wastewater treatment and methane production in a novel integrated upflow microbial electrolysis cell (Upflow-MEC). International Journal of Hydrogen Energy, 2016; 41(4): 2189–2196.

Cusick R D, Kiely P D, Logan B E. A monetary comparison of energy recovered from microbial fuel cells and microbial electrolysis cells fed winery or domestic wastewaters. International Journal of Hydrogen Energy, 2010; 35(17): 8855–8861.

Seifert K, Waligorska M, Laniecki M. Hydrogen generation in photobiological process from dairy wastewater. International Journal of Hydrogen Energy, 2010; 35(18): 9624–9629.

Montpart N, Rago L, Baeza J A, Guisasola A. Hydrogen production in single chamber microbial electrolysis cells with different complex substrates. Water Research, 2015; 68: 601–615.

Wang Y, Guo W, Xing D, Chang J, Ren N. Hydrogen production using biocathode single-chamber microbial electrolysis cells fed by molasses wastewater at low temperature. International Journal of Hydrogen Energy, 2014; 39(33): 19369–19375.

An Q, Wang J, Wang Y, Lin Z, Zhu M. Investigation on hydrogen production from paper sludge without inoculation and its enhancement by Clostridium thermocellum. Bioresource Technology, 2018; 263: 120–127.

Lin P, Whang L, Wu Y, Ren W, Hsiao C, Li S, et al. Biological hydrogen production of the genus Clostridium: Metabolic study and mathematical model simulation. International Journal of Hydrogen Energy, 2007; 32(12): 1728–1735.

Dhar B R, Elbeshbishy E, Hafez H, Lee H. Hydrogen production from sugar beet juice using an integrated biohydrogen process of dark fermentation and microbial electrolysis cell. Bioresource Technology, 2015; 198: 223–230.

Li X, Liang D, Bai Y, Fan Y, Hou H. Enhanced H2 production from corn stalk by integrating dark fermentation and single chamber microbial electrolysis cells with double anode arrangement. International Journal of Hydrogen Energy, 2014; 39(17): 8977–8982.

Lu L, Ren Z J. Microbial electrolysis cells for waste biorefinery: A state of the art review. Bioresource Technology, 2016; 215: 254–264.

Lalaurette E, Thammannagowda S, Mohagheghi A, Maness P, Logan B E. Hydrogen production from cellulose in a two-stage process combining fermentation and electrohydrogenesis. International Journal of Hydrogen Energy, 2009; 34(15): 6201–6210.

Wang A, Sun D, Cao G, Wang H, Ren N, Wu W, et al. Integrated hydrogen production process from cellulose by combining dark fermentation, microbial fuel cells, and a microbial electrolysis cell. Bioresource Technology, 2011; 102(5): 4137–4143.

Lu L, Ren N, Xing D, Logan B E. Hydrogen production with effluent from an ethanol-H2-coproducing fermentation reactor using a single-chamber microbial electrolysis cell. Biosensors and Bioelectronics, 2009; 24(10): 3055–3060.

Wu T, Zhu G, Jha A K, Zou R, Liu L, Huang X, et al. Hydrogen production with effluent from an anaerobic baffled reactor (ABR) using a single-chamber microbial electrolysis cell (MEC). International Journal of Hydrogen Energy, 2013; 38(25): 11117–11123.

Liu W, Huang S, Zhou A, Zhou G, Ren N, Wang A, et al. Hydrogen generation in microbial electrolysis cell feeding with fermentation liquid of waste activated sludge. International Journal of Hydrogen Energy, 2012; 37(18): 13859–13864.

Bajracharya S, Sharma M, Mohanakrishna G, Dominguez Benneton X, Strik D P B T, Sarma P M, et al. An overview on emerging bioelectrochemical systems (BESs): Technology for sustainable electricity, waste remediation, resource recovery, chemical production and beyond. Renewable Energy, 2016; 98: 153–170.

Sleutels T, Molenaar S, Heijne A, Buisman C. Low substrate loading limits methanogenesis and leads to high coulombic efficiency in bioelectrochemical systems. Microorganisms, 2016; 4(1): 7.

Zhang Y, Angelidaki I. Microbial electrolysis cells turning to be versatile technology: Recent advances and future challenges. Water Research, 2014; 56: 11–25.

Wang H, Ren Z J. A comprehensive review of microbial electrochemical systems as a platform technology. Biotechnology Advances, 2013; 31(8): 1796–1807.

Huang L, Cheng S, Chen G. Bioelectrochemical systems for efficient recalcitrant wastes treatment. Journal of Chemical Technology & Biotechnology, 2011; 86(4): 481–491.

Badia-Fabregat M, Rago L, Baeza J A, Guisasola A. Hydrogen production from crude glycerol in an alkaline microbial electrolysis cell. International Journal of Hydrogen Energy, 2019; 44(32): 17204–17213.

Lu L, Xing D, Ren N. Pyrosequencing reveals highly diverse microbial communities in microbial electrolysis cells involved in enhanced H2 production from waste activated sludge. Water Research, 2012; 46(7): 2425–2434.

Li X, Zheng R, Zhang X, Liu Z, Zhu R, Zhang X, et al. A novel exoelectrogen from microbial fuel cell: Bioremediation of marine petroleum hydrocarbon pollutants. Journal of Environmental Management, 2019; 235: 70–76.

Kadier A, Simayi Y, Abdeshahian P, Azman N F, Chandrasekhar K, Kalil M S. A comprehensive review of microbial electrolysis cells (MEC) reactor designs and configurations for sustainable hydrogen gas production. Alexandria Engineering Journal, 2016; 55(1): 427–443.

Ding A, Fan Q, Cheng R, Sun G, Zhang M, Wu D. Impacts of Applied Voltage on Microbial Electrolysis Cell-Anaerobic Membrane Bioreactor (MEC-AnMBR) and its membrane fouling mitigation mechanism. Chemical Engineering Journal, 2017.