References

1. D. Das, T.N. Veziroglu, Hydrogen production by biological processes: a survey of literature, Int. J. Hydrogen Energy, 26 (2001) 13–28.
2. K. Christopher, R. Dimitrios, A review on exergy comparison of hydrogen production methods from renewable energy sources, Energy Environ. Sci., 5 (2012) 6640–6651.
3. R. Abdallah, H. Djelal, A. Amrane, W. Sayed, F. Fourcade, T. Labasque, F. Geneste, S. Taha, D. Floner, Dark fermentative hydrogen production by anaerobic sludge growing on glucose and ammonium resulting from nitrate electroreduction, Int. J. Hydrogen Energy, 41 (2016) 5445–5455.
4. R. Navarro, M. Sanchez-Sanchez, M. Alvarez-Galvan, F. Del Valle, J. Fierro, Hydrogen production from renewable sources: biomass and photocatalytic opportunities, Energy Environ. Sci., 2 (2009) 35–54.
5. M.F. Awalludin, O. Sulaiman, R. Hashim, W.N.A.W. Nadhari, An overview of the oil palm industry in Malaysia and its waste utilization through thermochemical conversion, specifically via liquefaction, Renewable Sustainable Energy Rev., 50 (2015) 1469–1484.
6. T.Y. Wu, A.W. Mohammad, J.M. Jahim, N. Anuar, A holistic approach to managing palm oil mill effluent (POME): biotechnological advances in the sustainable reuse of POME, Biotechnol. Adv., 27 (2009) 40–52.
7. A. Tawfik, A. Salem, M. El-Qelish, Two stage anaerobic baffled reactors for bio-hydrogen production from municipal food waste, Bioresour. Technol., 102 (2011) 8723–8726.
8. I. Ntaikou, G. Antonopoulou, G. Lyberatos, Biohydrogen production from biomass and wastes via dark fermentation: a review, Waste Biomass Valorization, 1 (2010) 21–39.
9. I.C. Liu, L.M. Whang, W.J. Ren, P.Y. Lin, The effect of pH on the production of biohydrogen by clostridia: thermodynamic and metabolic considerations, Int. J. Hydrogen Energy, 36 (2011) 439–449.
10. M. Westerholm, J. Moestedt, A. Schnürer, Biogas production through syntrophic acetate oxidation and deliberate operating strategies for improved digester performance, Appl Energy, 179 (2016) 124–135.
11. R. Nandi, S. Sengupta, Microbial production of hydrogen: an overview, Crit. Rev. Microbiol., 24 (1998) 61–84.
12. S.K. Khanal, W.-H. Chen, L. Li, S. Sung, Biological hydrogen production: effects of pH and intermediate products, Int. J. Hydrogen Energy, 29 (2004) 1123–1131.
13. H.H. Fang, H. Liu, Effect of pH on hydrogen production from glucose by a mixed culture, Bioresour. Technol., 82 (2002) 87–93.
14. A.A. Zinatizadeh, M. Mirghorayshi, P.M. Birgani, P. Mohammadi, S. Ibrahim, Influence of thermal and chemical pretreatment on structural stability of granular sludge for high-rate hydrogen production in an UASB bioreactor, Int. J. Hydrogen Energy, 42 (2017) 20512–20519.
15. Y. Feng, Y. Liu, Y. Zhang, Enhancement of sludge decomposition and hydrogen production from waste activated sludge in a microbial electrolysis cell with cheap electrodes, Environ. Sci.: Water Res. Technol., 1 (2015) 761–768.
16. Y.-Y. Ning, D.-W. Jin, G.-P. Sheng, H. Harada, X.-Y. Shi, Evaluation of the stability of hydrogen production and microbial diversity by anaerobic sludge with chloroform treatment, Renewable Energy, 38 (2012) 253–257.
17. K. Zhang, N. Ren, C. Guo, A. Wang, G. Cao, Effects of various pretreatment methods on mixed microflora to enhance biohydrogen production from corn stover hydrolysate, J. Environ. Sci., 23 (2011) 1929–1936.
18. Y. Wong, J. Juan, A. Ting, T. Wu, High efficiency bio-hydrogen production from glucose revealed in an inoculum of heatpretreated landfill leachate sludge, Energy, 72 (2014) 628–635.
19. M. Cai, J. Liu, Y. Wei, Enhanced biohydrogen production from sewage sludge with alkaline pretreatment, Environ. Sci. Technol., 38 (2004) 3195–3202.
20. A. Akhbari, A. Zinatizadeh, P. Mohammadi, M. Irandoust, Y. Mansouri, Process modeling and analysis of biological nutrients removal in an integrated RBC-AS system using response surface methodology, Chem. Eng. J., 168 (2011) 269–279.
21. X.-J. Tang, G.-Q. He, Q.-H. Chen, X.-Y. Zhang, M.A. Ali, Medium optimization for the production of thermal stable β-glucanase by Bacillus subtilis ZJF-1A5 using response surface methodology, Bioresour. Technol., 93 (2004) 175–181.
22. M. Dinarvand, M. Rezaee, M. Masomian, S.D. Jazayeri, M. Zareian, S. Abbasi, A.B. Ariff, Effect of C/N ratio and media optimization through response surface methodology on simultaneous productions of intra-and extracellular inulinase and invertase from Aspergillus niger ATCC 20611, BioMed Res. Int., 508968 (2013) 13.
23. A. Ahmad, S. Ismail, S. Bhatia, Optimization of coagulation− flocculation process for palm oil mill effluent using response surface methodology, Environ. Sci. Technol., 39 (2005) 2828–2834.
24. A. Zinatizadeh, A. Mohamed, A. Abdullah, M. Mashitah, M.H. Isa, G. Najafpour, Process modeling and analysis of palm oil mill effluent treatment in an up-flow anaerobic sludge fixed film bioreactor using response surface methodology (RSM), Water Res., 40 (2006) 3193–3208.
25. O. Sompong, P. Prasertsan, N. Intrasungkha, S. Dhamwichukorn, N.-K. Birkeland, Optimization of simultaneous thermophilic fermentative hydrogen production and COD reduction from palm oil mill effluent by thermoanaerobacterium-rich sludge, Int. J. Hydrogen Energy, 33 (2008) 1221–1231.
26. C.Y.L. F.Y. Chang, Biohydrogen production using an up-flow anaerobic sludge blanket reactor, Int. J. Hydrogen energy, 29 (2004) 33.
27. A.P.H. Association, A.W.W. Association, W.P.C. Federation, W.E. Federation, Standard Methods for the Examination of Water and Wastewater, American Public Health Association, 1915.
28. J. Fermoso, M.V. Gil, B. Arias, M.G. Plaza, C. Pevida, J. Pis, F. Rubiera, Application of response surface methodology to assess the combined effect of operating variables on highpressure coal gasification for H₂-rich gas production, Int. J. Hydrogen Energy, 35 (2010) 1191–1204.
29. D.C. Montgomery, C.L. Jennings, M. Kulahci, Introduction to Time Series Analysis and Forecasting, John Wiley & Sons, Hoboken, 2015.
30. R.L. Mason, R.F. Gunst, J.L. Hess, Statistical Design and Analysis of Experiments: With Applications to Engineering and Science, John Wiley & Sons, United States, 2003.
31. R.A. Rahman, Kinetics and Performance of Sewage Sludge Treatment Using Liquid State Bioconversion in Continuous Bioreactor, Universiti Putra Malaysia, 2009.
32. M. Sarioglu, Ö.B. Gökçek, Treatment of automotive industry wastewater using anaerobic batch reactors: the influence of substrate/inoculum and molasses/wastewater, Process Saf. Environ., 102 (2016) 648–654.
33. Y. Tao, Y. He, Y. Wu, F. Liu, X. Li, W. Zong, Z. Zhou, Characteristics of a new photosynthetic bacterial strain for hydrogen production and its application in wastewater treatment, Int. J. Hydrogen Energy, 33 (2008) 963–973.
34. P. Mishra, S. Thakur, L. Singh, Z. Ab Wahid, M. Sakinah, Enhanced hydrogen production from palm oil mill effluent using two stage sequential dark and photo fermentation, Int. J. Hydrogen Energy, 41 (2016) 18431–18440.
35. E. Eroğlu, U. Gündüz, M. Yücel, L. Türker, İ. Eroğlu, Photobiological hydrogen production by using olive mill wastewater as a sole substrate source, Int. J. Hydrogen Energy, 29 (2004) 163–171.
36. F. Raposo, R. Borja, M. Martín, A. Martín, M. De la Rubia, B. Rincón, Influence of inoculum–substrate ratio on the anaerobic digestion of sunflower oil cake in batch mode: process stability and kinetic evaluation, Chem. Eng. J., 149 (2009) 70–77.
37. S. Manickam, S. Parthasarathy, I. Alzorqi, E.H. Ng, T.J. Tiong, R.L. Gomes, A. Ali, Role of H₂O₂ in the fluctuating patterns of COD (chemical oxygen demand) during the treatment of palm oil mill effluent (POME) using pilot scale triple frequency ultrasound cavitation reactor, Ultrasonics Sonochem., 21 (2014) 1519–1526.
38. S.K. Leong, N.A.A. Bashah, Kinetic study on cod removal of palm oil refinery effluent by UV-Fenton, APCBEE Procedia, 3 (2012) 6–10.
39. Z.Y. Hitit, C.Z. Lazaro, P.C. Hallenbeck, Hydrogen production by co-cultures of Clostridium butyricum and Rhodospeudomonas palustris: optimization of yield using response surface methodology, Int. J. Hydrogen Energy, 42 (2017) 6578–6589.
40. J. Cheng, H. Su, J. Zhou, W. Song, K. Cen, Hydrogen production by mixed bacteria through dark and photo fermentation, Int. J. Hydrogen Energy, 36 (2011) 450–457.
41. A. Reungsang, C. Sreela-or, Bio-hydrogen production from pineapple waste extract by anaerobic mixed cultures, Energies, 6 (2013) 2175–2190.
42. M. Elsamadony, A. Tawfik, A. Danial, M. Suzuki, Use of Carica papaya enzymes for enhancement of H₂ production and degradation of glucose, protein, and lipids, Energy Procedia, 75 (2015) 975–980.
43. Y.K. Oh, S.H. Kim, M.S. Kim, S. Park, Thermophilic biohydrogen production from glucose with trickling biofilter, Biotechnol. Bioeng., 88 (2004) 690–698.
44. C.L. Li, H.H.P. Fang, Fermentative hydrogen production from wastewater and, solid wastes by mixed cultures, Crit. Rev. Environ. Sci. Technol., 37 (2007) 1.
45. Z.P. Zhang, S.S. Adav, K.Y. Show, J.H. Tay, D.T. Liang, D.J. Lee, A. Su, Characteristics of rapidly formed hydrogen‐producing granules and biofilms, Biotechnol. Bioeng., 101 (2008) 926–936.
46. Y. Akutsu, Y.-Y. Li, H. Harada, H.-Q. Yu, Effects of temperature and substrate concentration on biological hydrogen production from starch, Int. J. Hydrogen Energy, 34 (2009) 2558–2566.
47. C. Garcia, F. Molina, E. Roca, J.M. Lema, Fuzzy-based control of an anaerobic reactor treating wastewaters containing ethanol and carbohydrates, Ind. Eng. Chem. Res., 46 (2007) 6707–6715.
48. B.K. Penumathsa, G.C. Premier, G. Kyazze, R. Dinsdale, A.J. Guwy, S. Esteves, J. Rodríguez, ADM1 can be applied to continuous bio-hydrogen production using a variable stoichiometry approach, Water Res., 42 (2008) 4379–4385.
49. G. Gnanapragasam, M. Senthilkumar, V. Arutchelvan, T. Velayutham, S. Nagarajan, Bio-kinetic analysis on treatment of textile dye wastewater using anaerobic batch reactor, Bioresour. Technol., 102 (2011) 627–632.
50. J. Ma, L. Yu, C. Frear, Q. Zhao, X. Li, S. Chen, Kinetics of psychrophilic anaerobic sequencing batch reactor treating flushed dairy manure, Bioresour. Technol., 131 (2013) 6–12.