References

1. S.B. Tsai, Y. Xue, J. Zhang, Q. Chen, Y. Liu, J. Zhou, W. Dong, Models for forecasting growth trends in renewable energy, Renew. Sust. Energ. Rev., 77 (2016) 1169–1178.
2. Y. Liu, H. Xiao, Y. Lv, N. Zhang, The effect of new-type urbanization on energy consumption in China: a spatial econometric analysis, J. Clean. Prod., 163 (2017) S299–S305.
3. Z. Shao, Current situation and countermeasures of water environment pollution, China Resour. Compr. Util., 35 (2017) 14–15. (In Chinese)
4. R.Y. Tamakloe, Effect of COD and H₂O₂ concentration on DC–MFC, Renew. Energy, 83 (2015) 1299–1304.
5. C. Sakdaronnarong, A. Ittitanakam, W. Tanubumrungsuk, S. Chaithong, S. Thanosawan, N. Sinbuathong, C. Jeraputra, Potential of lignin as a mediator in combined systems for biomethane and electricity production from ethanol stillage wastewater, Renew. Energy, 76 (2015) 242–248.
6. J. Winfield, I. Gajda, J. Greenman, I. Ieropoulos, A review into the use of ceramics in microbial fuel cells, Bioresour. Technol., 215 (2016) 296–303.
7. D.J. Lee, J.S. Chang, J.Y. Lai, Microalgae–microbial fuel cell: A mini review, Bioresour. Technol., 198 (2015) 891–895.
8. A. Elmekawy, H.M. Hegab, X. Dominguezbenetton, D. Pant, Internal resistance of microfluidic microbial fuel cell: challenges and potential opportunities, Bioresour. Technol., 142 (2013) 672–682.
9. M.H. Cho, S. Kalathil, S.H. Shim, Y.H. Lee, J. Lee, Simultaneous decolorization of mixed dye wastewater and electricity generation using a two chambered microbial fuel cell, J. Biotechnol., 150 (2010) 239–239.
10. Y.S. Oon, S.A. Ong, L.N. Ho, Y.S. Wong, Y.L. Oon, H.K. Lehl, W.E. Thung, Long-term operation of double chambered microbial fuel cell for bio-electrodenitrification, Bioprocess Bioprocess Biosyst. Eng., 39 (2016) 893–900.
11. Y. Yu, J. Zhao, S. Wang, H. Zhao, X. Ding, K. Gao, Nitrogen removal and electricity production at a double-chamber microbial fuel cell with cathode nitrite denitrification, Environ. Technol., 38 (2017) 3093–3101.
12. X.X. Cao, X. Huang, X. Zhang, P. Liang, M. Fan, A mini-microbial fuel cell for voltage testing of exoelectrogenic bacteria, Front. Environ. Sci. Eng. China, 3 (2009) 307–312.
13. G. Zhou, Y. Zhou, G. Zhou, L. Lu, X. Wan, H. Shi, Assessment of a novel overflow-type electrochemical membrane bioreactor (EMBR) for wastewater treatment, energy recovery and membrane fouling mitigation, Bioresour. Technol., 196 (2015) 648–655.
14. Y. Wu, X. Zhao, M. Jin, Y. Li, S. Li, F. Kong, J. Nan, A. Wang, Copper removal and microbial community analysis in single-chamber microbial fuel cell, Bioresour. Technol., 253 (2018) 372–377.
15. B.G. Zhang, Z.J. Wang, X. Zhou, C.H. Shi, H.M. Guo, C.P. Feng, Electrochemical decolorization of methyl orange powered by bioelectricity from single-chamber microbial fuel cells, Bioresour. Technol., 181 (2015) 360–362.
16. J. Wei, P. Liang, X. Huang, Recent progress in electrodes for microbial fuel cells, Bioresour. Technol., 102 (2011) 9335–9344.
17. B. Min, B.E. Logan, Continuous Electricity generation from domestic wastewater and organic substrates in a flat plate microbial fuel cell, Environ. Sci. Technol., 38 (2004) 5809–5814.
18. D.Q. Jiang, B.K. Li, Granular activated carbon single-chamber microbial fuel cells (GAC–SCMFCs): a design suitable for large-scale wastewater treatment processes, Biochem. Eng. J., 47 (2009) 31–37.
19. U. Karra, E. Muto, R. Umaz, M. Kölln, C. Santoro, W. Lei, B. Li, Performance evaluation of activated carbon-based electrodes with novel power management system for long-term benthic microbial fuel cells, Int. J. Hydrogen Energ., 39 (2014) 21847– 21856.
20. C. Santoro, K. Artyushkova, S. Babanova, P. Atanassov, I. Ieropoulos, M. Grattieri, P. Cristiani, S. Trasatti, B. Li, A.J. Schuler, Parameters characterization and optimization of activated carbon (AC) cathodes for microbial fuel cell application, Bioresour. Technol., 163 (2014) 54–63.
21. T. Yamashita, M. Ishida, S. Asakawa, H. Kanamori, H. Sasaki, A. Ogino, Y. Katayose, T. Hatta, H. Yokoyama, Enhanced electrical power generation using flame-oxidized stainless steel anode in microbial fuel cells and the anodic community structure, Biotechnol. Biofuels, 9 (2016) 1–10.
22. R.S. Berk, J.H. Canfield, Bioelectrochemical energy conversion, Appl. Microbiol., 12 (1964) 10–12.
23. A.G.D. Campo, P. Cañizares, M.A. Rodrigo, F.J. Fernández, J. Lobato, Microbial fuel cell with an algae-assisted cathode: A preliminary assessment, J. Power Sources, 242 (2013) 638–645.
24. D.F. Juang, C.H. Lee, S.C. Hsueh, Comparison of electrogenic capabilities of microbial fuel cell with different light power on algae grown cathode, Bioresour. Technol., 123 (2012) 23–29.
25. M.S. Venkata, S. Srikanth, P. Chiranjeevi, S. Arora, R. Chandra, Algal biocathode for in situ terminal electron acceptor (TEA) production: Synergetic association of bacteria-microalgae metabolism for the functioning of biofuel cell, Bioresour. Technol., 166 (2014) 566–574.
26. Z.D. Liu, L. Jing, S.P. Zhang, Z.G. Su, Study of operational performance and electrical response on mediator-less microbial fuel cells fed with carbon- and protein-rich substrates, Biochem. Eng. J., 45 (2009) 185–191.
27. D. Pant, G.V. Bogaert, L. Diels, K. Vanbroekhoven, A review of the substrates used in microbial fuel cells (MFCs) for sustainable energy production, Bioresour. Technol., 101 (2010) 1533–1543.
28. K.J. Chae, M.J. Choi, J.W. Lee, K.Y. Kim, I.S. Kim, Effect of different substrates on the performance, bacterial diversity, and bacterial viability in microbial fuel cells, Bioresour. Technol., 100 (2009) 3518–3525.
29. C. Feng, C.C. Tsai, C.Y. Ma, C.P. Yu, C.H. Hou, Integrating cost-effective microbial fuel cells and energy-efficient capacitive deionization for advanced domestic wastewater treatment, Chem. Eng. J., 330 (2017) 1–10.
30. J. Yu, J. Seon, Y. Park, S. Cho, T. Lee, Electricity generation and microbial community in a submerged-exchangeable microbial fuel cell system for low-strength domestic wastewater treatment, Bioresour. Technol., 117 (2012) 172–179.
31. W.E. Thung, S.A. Ong, L.N. Ho, Y.S. Wong, F. Ridwan, Y.L. Oon, Y.S. Oon, H.K. Lehl, A highly efficient single chambered up-flow membrane-less microbial fuel cell for treatment of azo dye Acid Orange 7-containing wastewater, Bioresour. Technol., 197 (2015) 284–288.
32. H. Zou, Y. Wang, Azo dyes wastewater treatment and simultaneous electricity generation in a novel process of electrolysis cell combined with microbial fuel cell, Bioresour. Technol., 235 (2017) 167–175.
33. C. Kim, C.R. Lee, Y.E. Song, J. Heo, S.M. Choi, D.H. Lim, J. Cho, C. Park, J. Min, J.R. Kim, Hexavalent chromium as a cathodic electron acceptor in a bipolar membrane microbial fuel cell with the simultaneous treatment of electroplating wastewater, Chem. Eng. J., 328 (2017) 703–707.
34. B. Min, J. Kim, S. Oh, J.M. Regan, B.E. Logan, Electricity generation from swine wastewater using microbial fuel cells, Water Res., 39 (2005) 4961–4968.
35. L. Zhuang, Y. Yuan, Y. Wang, S. Zhou, Long-term evaluation of a 10-liter serpentine-type microbial fuel cell stack treating brewery wastewater, Bioresour. Technol., 123 (2012) 406–412.
36. Q. Wen, Y. Wu, D. Cao, L. Zhao, Q. Sun, Electricity generation and modeling of microbial fuel cell from continuous beer brewery wastewater, Bioresour. Technol., 100 (2009) 4171–4175.
37. J. Yu, Y. Park, B. Kim, T. Lee, Power densities and microbial communities of brewery wastewater-fed microbial fuel cells according to the initial substrates, Bioprocess Biosyst. Eng., 38 (2015) 85–92.
38. Y.L. Oon, S.A. Ong, L.N. Ho, Y.S. Wong, F.A. Dahalan, Y.S. Oon, H.K. Lehl, W.E. Thung, N. Nordin, Role of macrophyte and effect of supplementary aeration in up-flow constructed wetland- microbial fuel cell for simultaneous wastewater treatment and energy recovery, Bioresour. Technol., 224 (2016) 265–275.
39. J. Wang, X. Song, Y. Wang, B. Abayneh, Y. Li, D. Yan, J. Bai, Nitrate removal and bioenergy production in constructed wetland coupled with microbial fuel cell: Establishment of electrochemically active bacteria community on anode, Bioresour. Technol., 221 (2016) 358–365.
40. M. Li, S. Zhou, M. Xu, Graphene oxide supported magnesium oxide as an efficient cathode catalyst for power generation and wastewater treatment in single chamber microbial fuel cells, Chem. Eng. J., 328 (2017) 106–116.
41. H. Song, S. Zhang, X. Long, X. Yang, H. Li, W. Xiang, Optimization of bioelectricity generation in constructed wetland-coupled microbial fuel cellsystems, Water, 9 (2017) 185.
42. J. Wang, X. Song, Y. Wang, B. Abayneh, D. Yi, D. Yan, J. Bai, Microbial community structure of different electrode materials in constructed wetland incorporating microbial fuel cell, Bioresour. Technol., 221 (2016) 697–702.
43. A. Dube, R. David, P. Ngulube, A cost-benefit analysis of document management strategies used at a financial institution in Zimbabwe: a case study, S. Afr. J. Inf. Manage., 15 (2013) 1–10.
44. M. Santamaría, D. Azqueta, Promoting biofuels use in Spain: a cost-benefit analysis. Renew. Sust. Energ. Rev., 50 (2015) 1415– 1424.
45. M. Djukic, I.J. Ivanovic, O.M. Ivanovic, M. Lazic, D. Bodroza, Cost-benefit analysis of an infrastructure project and a cost-reflective tariff: a case study for investment in wastewater treatment plant in Serbia. Renew. Sust. Energ. Rev., 59 (2016) 1419–1425.
46. T.C. Pan, J.J. Kao, C.P. Wong, Effective solar radiation based benefit and cost analyses for solar water heater development in Taiwan, Renew. Sust. Energ. Rev., 16 (2012) 1874–1882.
47. X. Sun, H. Xu, Q. Zhu, L. Lu, H. Zhao, Synthesis of Nafion®-stabilized Pt nanoparticles to improve the durability of proton exchange membrane fuel cell, J. Energ. Chem., 24 (2015) 359–365.
48. X. Tan, L. Shi, Z. Ma, X. Zhang, G. Lu, Institutional analysis of sewage treatment charge based on operating cost of sewage treatment plant–an empirical research of 227 samples in China, China Environ. Sci., 35 (2015) 3833–3840. (In Chinese)
49. P. Coquillard, A. Muzy, F. Diener, Optimal phenotypic plasticity in a stochastic environment minimises the cost/benefit ratio, Ecol. Model., 242 (2012) 28–36.
50. A. Coleman, A. Grimes, Betterment taxes, capital gains and benefit cost ratios, Econ. Lett., 109 (2010) 54–56.
51. H.O. Mohamed, M. Obaid, E.T. Sayed, Y. Liu, J. Lee, M. Park, B. Nam, H.Y. Kim, Electricity generation from real industrial wastewater using a single-chamber air cathode microbial fuel cell with an activated carbon anode, Bioprocess Biosyst. Eng., 40 (2017) 1151–1161.
52. L. Huang, X. Li, Y. Ren, X. Wang, In-situ modified carbon cloth with polyaniline/graphene as anode to enhance performance of microbial fuel cell, Int. J. Hydrogen Energ., 41 (2016) 11369– 11379.
53. S.J. You, J.N. Zhang, Y.X. Yuan, N.Q. Ren, X.H. Wang, Development of microbial fuel cell with anoxic/oxic design for treatment of saline seafood wastewater and biological electricity generation, J. Chem. Technol. Biotechnol., 85 (2010) 1077–1083.
54. B.K. Min, S.A. Cheng, B.E. Logan, Electricity generation using membrane and salt bridge microbial fuel cells, Water Res., 39 (2005) 1675–1686.
55. W. Li, J. Sun, Y. Hu, Y. Zhang, F. Deng, J. Chen, Simultaneous pH self-neutralization and bioelectricity generation in a dual bioelectrode microbial fuel cell under periodic reversion of polarity, J. Power Sources, 268 (2014) 287–293.
56. Z. Liu, X. Li, B. Jia, Y. Zheng, L. Fang, Q. Yang, D. Wang, G. Zeng, Production of electricity from surplus sludge using a single chamber floating-cathode microbial fuel cell, Water Sci. Technol., 60 (2009) 2399–2404.
57. J. Sun, W. Li, Y. Li, Y. Hu, Y. Zhang, Redox mediator enhanced simultaneous decolorization of azo dye and bioelectricity generation in air-cathode microbial fuel cell, Bioresour. Technol., 142 (2013) 407–414.
58. X.Y. Wu, T.S. Song, X.J. Zhu, P. Wei, C.C. Zhou, Construction and operation of microbial fuel cell with Chlorella vulgaris biocathode for electricity generation, Appl. Biochem. Biotechnol. 171 (2013) 2082–2092.
59. L. Wang, X. Li, L. Wang, Study on wastewater treatment by wetland type microbial fuel cell and simultaneous electricity generation, Mod. Chem. Ind., 37 (2017) 154–157. (In Chinese).
60. F. Zhou, C. Xian, X. Li, W. Hui, X. Li, Electrode and azo dye decolorization performance in microbial-fuel-cell-coupled constructed wetlands with different electrode size during long-term wastewater treatment, Bioresour. Technol., 238 (2017) 450–460.
61. Y.L. Oon, S.A. Ong, L.N. Ho, Y.S. Wong, F.A. Dahalan, Y.S. Oon, H.K. Lehl, W.E. Thung, Synergistic effect of up-flow constructed wetland and microbial fuel cell for simultaneous wastewater treatment and energy recovery, Bioresour. Technol., 203 (2016) 190–197.
62. F. Xu, F.Q. Cao, Q. Kong, L.L. Zhou, Q. Yuan, Y.J. Zhu, Q. Wang, Y.D. Du, Z.D. Wang, Electricity production and evolution of microbial community in the constructed wetland-microbial fuel cell, Chem. Eng. J., 339 (2018) 479–486.
63. D. Xing, S. Cheng, J.M. Regan, B.E. Logan, Change in microbial communities in acetate- and glucose-fed microbial fuel cells in the presence of light, Biosens. Bioelectron., 25 (2010) 105–111.
64. H. Liu, B.E. Logan, Electricity generation using an air-cathode single chamber microbial fuel cell in the presence and absence of a proton exchange membrane, Environ. Sci. Technol., 38 (2004) 4040–4046.
65. X.T. Zheng, A. Ananthanarayanan, K.Q. Luo, P. Chen, Glowing graphene quantum dots and carbon dots: properties, syntheses, and biological applications, Small, 11 (2015) 1620–1636.
66. E. Stavrinidou, R. Gabrielsson, E. Gomez, X. Crispin, O. Nilsson, D. T. Simon, M. Berggren, Electronic plants, Sci. Adv., 1 (2015) e1501136.
67. J. Arias, E. Artucb, D. Lederman, D. Rojasc, Trade, informal employment and labor adjustment costs, J. Dev. Econ., 133 (2018) 396–414.
68. H.T. Peng, Y. Liu, How government subsidies promote the growth of entrepreneurial companies in clean energy industry: An empirical study in China, J. Clean. Prod., 188 (2018) 508–520.
69. C. Santoro, C. Arbizzani, B. Erable, I. Ieropoulos, Microbial fuel cells: From fundamentals to applications, J. Power Sources, 356 (2017) 225–244.
70. X.X. Cao, X. Huang, P. Liang, K. Xiao, Y.J. Zhou, X.Y. Zhang, B.E. Logan, A new method for water desalination using microbial desalination cells, Environ. Sci. Technol., 43 (2009) 7148–7152.