References

1. A.R. Sheik, E.E.L. Muller, P. Wilmes, A hundred years of activated sludge: time for a rethink, Front. Microbiol., 5 (2014) 47.
2. Y. Xu, Y. Fang, Z. Wang, D. Guo, Y. Liu, Y. Huang, P. Fu, J. Jin, C. Wei, H. Wang, T. Zeng, In-situ sludge reduction and carbon reuse in an anoxic/oxic process coupled with hydrocyclone breakage, Water Res., 141 (2018) 135–144.
3. X. Cheng, S. Li, X. Liu, C. Peng, The process research of anaerobic flora disintegrating excess sludge, Desal. Wat. Treat., 56 (2015) 1888–1897.
4. T. Niu, Z. Zhou, X. Shen, W. Qiao, L.M. Jiang, W. Pan, J. Zhou, Effects of dissolved oxygen on performance and microbial community structure in a micro-aerobic hydrolysis sludge in situ reduction process, Water Res., 90 (2016) 369–377.
5. X. Li, X. Liu, S. Wu, A. Rasool, J. Zuo, C. Li, G. Liu, Microbial diversity and community distribution in different functional zones of continuous aerobic–anaerobic coupled process for sludge in situ reduction, Chem. Eng. J., 257 (2014) 74–81.
6. Z. Zhou, W. Qiao, C. Xing, Y. An, X. Shen, W. Ren, L.-M. Jiang, L. Wang, Microbial community structure of anoxic–oxic settling-anaerobic sludge reduction process revealed by 454-pyrosequencing, Chem. Eng. J., 266 (2015) 249–257.
7. V. Sodhi, A. Bansal, M.K. Jha, Excess sludge disruption and pollutant removal from tannery effluent by upgraded activated sludge system, J. Environ. Manage., 220 (2018) 87–95.
8. Z. Lewandowski, J.P. Boltz, 4.15–Biofilms in Water and Wastewater Treatment, in: Treatise on Water Science, Vol. 4, 2011, pp. 529–570.
9. Y.L. Wang, S. Xue, H. Wang, X. Xu, B. Liu, W. Wang, F. Xu, J. Jia, Characteristics of nitrogen removal and sludge reduction using a multi-redox environment coupled bioreactor, Desal. Wat. Treat., 132 (2018) 89–98.
10. T. Liu, G. Jia, X. Quan, Accelerated start-up and microbial community structures of simultaneous nitrification and denitrification using novel suspended carriers, J. Chem. Technol. Biotechnol., 93 (2017) 577–584.
11. Y. Wang, B. Liu, K. Zhang, Y. Liu, X. Xu, J. Jia, Investigate of in situ sludge reduction in sequencing batch biofilm reactor: performances, mechanisms and comparison of different carriers, Front. Environ. Sci. Eng. China, 12 (2018) 5.
12. B. Gong, Y. Wang, J. Wang, Y. Dou, J. Zhou, In situ excess sludge reduction in SBBR through uncoupling of metabolism induced by novel aeration modes, RSC Adv., 7 (2017) 29058–29064.
13. J. Zhao, L. Feng, G. Yang, D. Chen, J. Mu, Development of simultaneous nitrification-denitrification (SND) and organics removal in biofilm reactors with partially coupled a novel biodegradable carrier for nitrogen-rich water purification, Bioresour. Technol., 243 (2017) 800–809.
14. J. Zhang, L. Zhang, Y. Miao, Y. Sun, X. Li, Q. Zhang, Y. Peng, Feasibility of in situ enriching anammox bacteria in a sequencing batch biofilm reactor (SBBR) for enhancing nitrogen removal of real domestic wastewater, Chem. Eng. J., 325 (2018) 847–854.
15. L. Miao, Q. Zhang, S. Wang, B. Li, Z. Wang, S. Zhang, M. Zhang, Y. Peng, Characterization of EPS compositions and microbial community in an Anammox SBBR system treating landfill leachate, Bioresour. Technol., 249 (2017) 108–116.
16. D. Zheng, Q. Chang, M. Gao, Z. She, C. Jin, L. Guo, Y. Zhao, S. Wang, X. Wang, Performance evaluation and microbial community of a sequencing batch biofilm reactor (SBBR) treating mariculture wastewater at different chlortetracycline concentrations, J. Environ. Manage., 182 (2016) 496–504.
17. APHA, Standard Methods for the Examination of Water and Wastewater, Washington, D.C., USA, 2005.
18. L. Baozhen, Study on Characteristics of Combined Process of A²O Sludge in Suit Reduction Coupled Phosphorus Removal by Side-Stream, Shandong Jianzhu University, Jinan, 2017.
19. B.J. Ni, M. Ruscalleda, C. Pellicer-Nàcher, B.F. Smets, Modeling nitrous oxide production during biological nitrogen removal via nitrification and denitrification: extensions to the general ASM models, Environ. Sci. Technol., 47 (2013) 11908–11909.
20. S. Yang, W. Guo, Y. Chen, S. Peng, J. Du, H. Zheng, X. Feng, N. Ren, Simultaneous in-situ sludge reduction and nutrient removal in an A2MO-M system: performances, mechanisms, and modeling with an extended ASM2d model, Water Res., 88 (2016) 524–537.
21. L.C.X.H. Zheng, The mechanism of effect on N₂O production of carbon source types in denitrifying phosphorus removal process, J. Shandong Univ. (Eng. Sci.), 44 (2014) 72–77.
22. Y. Tian, Z. Li, Y. Ding, Y. Lu, Identification of the change in fouling potential of soluble microbial products (SMP) in membrane bioreactor coupled with worm reactor, Water Res., 47 (2013) 2015–2024.
23. G.-H. Chen, K.-J. An, S. Saby, E. Brois, M. Djafer, Possible cause of excess sludge reduction in an oxic-settling-anaerobic activated sludge process (OSA process), Water Res., 37 (2003) 3855–3866.
24. X.E. Kabushiki Kaisha, Biological Phase Diagnosis of Sewage Treatment, Chemical Industry Press, Beijing, China, 2012.
25. Y. Zheng, M. Xing, L. Cai, T. Xiao, Y. Lu, J. Jiang, Interaction of earthworms-microbe facilitating biofilm dewaterability performance during wasted activated sludge reduction and stabilization, Sci. Total Environ., 581 (2017) 573.
26. X. Ma, M. Xing, W. Yin, X. Zhe, Y. Jian, Microbial enzyme and biomass responses: deciphering the effects of earthworms and seasonal variation on treating excess sludge, J. Environ. Manage., 170 (2016) 207–214.
27. A.L. Eusebi, P. Battistoni, Reduction of the excess sludge production by biological alternating process: real application results and metabolic uncoupling mechanism, Environ. Technol., 36 (2015) 137–148.
28. Y. Wang, J. Li, W. Jia, N. Wang, H. Wang, S. Zhang, G. Chen, Enhanced nitrogen and phosphorus removal in the A2/O process by hydrolysis and acidification of primary sludge, Desal. Wat. Treat., 52 (2014) 5144–5151.
29. W. Lan, Y. Li, Q. Bi, Y. Hu, Reduction of excess sludge production in sequencing batch reactor (SBR) by lysis–cryptic growth using homogenization disruption, Bioresour. Technol., 134 (2013) 43–50.
30. L. Sun, L. Chen, S. Cai, W. Guo, T. Ye, Y. Cui, Effect of sludge reduction in oxic-settling-anaerobic (OSA) systems with different anaerobic hydraulic retention times (HRTs), Desal. Wat. Treat., 57 (2016) 1–5.
31. State Environmental Protection Administration (SEPA), Discharge Standard of Pollutants for Municipal Wastewater Treatment Plant (GB18918−2002), Beijing, China, 2002.
32. A.R. Johnsen, U. Karlson, Evaluation of bacterial strategies to promote the bioavailability of polycyclic aromatic hydrocarbons, Appl. Microbiol. Biotechnol., 63 (2004) 452–459.
33. A. Khursheed, A.A. Kazmi, Retrospective of ecological approaches to excess sludge reduction, Water Res., 45 (2011) 4287–4310.
34. J. Wang, X. Li, W. Fu, S. Wu, C. Li, Treatment of artificial soybean wastewater anaerobic effluent in a continuous aerobic-anaerobic coupled (CAAC) process with excess sludge reduction, Bioresour. Technol., 126 (2012) 142–147.
35. X. Yue, Y.K.K. Koh, H.Y. Ng, Effects of dissolved organic matters (DOMs) on membrane fouling in anaerobic ceramic membrane bioreactors (AnCMBRs) treating domestic wastewater, Water Res., 86 (2015) 96–107.
36. H. Yamamura, K. Okimoto, K. Kimura, Y. Watanabe, Hydrophilic fraction of natural organic matter causing irreversible fouling of microfiltration and ultrafiltration membranes, Water Res., 54 (2014) 123–136.
37. Z. Zhen, W. Qiao, C. Xing, X. Shen, D. Hu, L. Wang, A microaerobic hydrolysis process for sludge in situ reduction: performance and microbial community structure, Bioresour. Technol., 173 (2014) 452–456.