Cultivation in wastewaters for energy: A microalgae platform

Applied Energy

Volumn 179, Issue , 2016, Pages 609-625

  Cheah, Wai Yan ^a   Ling, Tau Chuan ^a   Show, Pau Loke ^b   Juan, Joon Ching ^c,d   Chang, Jo Shu ^e   Lee, Duu Jong ^f  

^a UNIVERSITY OF MALAYA   (Malaysia)

^b UNIVERSITY OF NOTTINGHAM MALAYSIA CAMPUS   (Malaysia)

^c MONASH UNIVERSITY MALAYSIA   (Malaysia)

^d UNIVERSITY OF MALAYA   (Malaysia)

^e NATIONAL CHENG KUNG UNIVERSITY   (Taiwan)

^f NATIONAL TAIWAN UNIVERSITY   (Taiwan)

Author keywords

Biofuel; Microalgae; Pollutants removal; Wastewater

Indexed keywords

ALGAE; CARBON; CARBON DIOXIDE; COST EFFECTIVENESS; EFFLUENTS; LEACHATE TREATMENT; MICROORGANISMS; PALM OIL; POLLUTION; SEWAGE; WASTEWATER; WASTEWATER TREATMENT;

BIO-BASED CHEMICALS; BIOFUEL PRODUCTION; LANDFILL LEACHATES; MICRO-ALGAE; MICROALGAL BIOMASS; MICROALGAL CULTIVATIONS; PALM OIL MILL EFFLUENTS; POLLUTANTS REMOVAL;

BIOFUELS;

BIOFUEL; BIOLOGICAL PRODUCTION; BIOMASS; BIOTECHNOLOGY; MICROALGA; POLLUTANT REMOVAL; WASTEWATER; WATER TREATMENT;

EID: 84978863683     PISSN: 03062619     EISSN: None     Source Type: Journal    
DOI: 10.1016/j.apenergy.2016.07.015     Document Type: Review

References (129)

1. [1] Rogers, J.N., Rosenberg, J.N., Guzman, B.J., Oh, V.H., Mimbela, L.E., Ghassemi, A., et al. A critical analysis of paddlewheel-driven raceway ponds for algal biofuel production at commercial scales. Algal Res 4 (2014), 76–88.
2. [2] Lam, M.K., Lee, K.T., Renewable and sustainable bioenergies production from palm oil mill effluent (POME): win–win strategies toward better environmental protection. Biotechnol Adv 29 (2011), 124–141.
3. [3] Bhatnagar, A., Chinnasamy, S., Singh, M., Das, K., Renewable biomass production by mixotrophic algae in the presence of various carbon sources and wastewaters. Appl Energy 88 (2011), 3425–3431.
4. [4] Nascimento, I.A., Marques, S.S.I., Cabanelas, I.T.D., Pereira, S.A., Druzian, J.I., de Souza, C.O., et al. Screening microalgae strains for biodiesel production: lipid productivity and estimation of fuel quality based on fatty acids profiles as selective criteria. Bioenergy Res 6 (2012), 1–13.
5. [5] McGinn, P.J., Dickinson, K.E., Bhatti, S., Frigon, J.-C., Guiot, S.R., O'Leary, S.J., Integration of microalgae cultivation with industrial waste remediation for biofuel and bioenergy production: opportunities and limitations. Photosynth Res 109 (2011), 231–247.
6. [6] Zhou, W., Chen, P., Min, M., Ma, X., Wang, J., Griffith, R., et al. Environment-enhancing algal biofuel production using wastewaters. Renew Sustain Energy Rev 36 (2014), 256–269.
7. [7] Patil, V., Tran, K.-Q., Giselrød, H.R., Towards sustainable production of biofuels from microalgae. Int J Mol Sci 9 (2008), 1188–1195.
8. [8] Gong, Y., Jiang, M., Biodiesel production with microalgae as feedstock: from strains to biodiesel. Biotechnol Lett 33 (2011), 1269–1284.
9. [9] Rawat, I., Ranjith Kumar, R., Mutanda, T., Bux, F., Biodiesel from microalgae: a critical evaluation from laboratory to large scale production. Appl Energy 103 (2013), 444–467.
10. [10] Chen, G., Zhao, L., Qi, Y., Enhancing the productivity of microalgae cultivated in wastewater toward biofuel production: a critical review. Appl Energy 137 (2015), 282–291.
11. [11] Pittman, J.K., Dean, A.P., Osundeko, O., The potential of sustainable algal biofuel production using wastewater resources. Bioresour Technol 102 (2011), 17–25.
12. [12] Unnithan, V.V., Unc, A., Smith, G.B., Mini-review: a priori considerations for bacteria–algae interactions in algal biofuel systems receiving municipal wastewaters. Algal Res 4 (2014), 35–40.
13. [13] Wang, L., Min, M., Li, Y., Chen, P., Chen, Y., Liu, Y., et al. Cultivation of green algae Chlorella sp. in different wastewaters from municipal wastewater treatment plant. Appl Biochem Biotechnol 162 (2010), 1174–1186.
14. [14] Sturm, B.S., Lamer, S.L., An energy evaluation of coupling nutrient removal from wastewater with algal biomass production. Appl Energy 88 (2011), 3499–3506.
15. 2. Appl Energy 88 (2011), 3336–3341.
16. [16] Cabanelas, I.T.D., Arbib, Z., Chinalia, F.A., Souza, C.O., Perales, J.A., Almeida, P.F., et al. From waste to energy: microalgae production in wastewater and glycerol. Appl Energy 109 (2013), 283–290.
17. [17] Amaro, H.M., Guedes, A., Malcata, F.X., Advances and perspectives in using microalgae to produce biodiesel. Appl Energy 88 (2011), 3402–3410.
18. [18] Zhou, W., Li, Y., Min, M., Hu, B., Zhang, H., Ma, X., et al. Growing wastewater-born microalga Auxenochlorella protothecoides UMN280 on concentrated municipal wastewater for simultaneous nutrient removal and energy feedstock production. Appl Energy 98 (2012), 433–440.
19. [19] Ahmad, A., Ghufran, R., Wahid, Z.A., Bioenergy from anaerobic degradation of lipids in palm oil mill effluent. Rev Environ Sci Bio/Technol 10 (2011), 353–376.
20. [20] Saenge, C., Cheirsilp, B., Suksaroge, T.T., Bourtoom, T., Efficient concomitant production of lipids and carotenoids by oleaginous red yeast Rhodotorula glutinis cultured in palm oil mill effluent and application of lipids for biodiesel production. Biotechnol Bioprocess Eng 16 (2011), 23–33.
21. [21] Hosseini, S.E., Wahid, M.A., Feasibility study of biogas production and utilization as a source of renewable energy in Malaysia. Renew Sustain Energy Rev 19 (2013), 454–462.
22. [22] Alam, M.Z., Kabbashi, N.A., Hussin, S.N.I., Production of bioethanol by direct bioconversion of oil-palm industrial effluent in a stirred-tank bioreactor. J Ind Microbiol Biotechnol 36 (2009), 801–808.
23. [23] Kampschreur, M.J., van Loosdrecht, M.C., Finding the balance between greenhouse gas emission and energy efficiency of wastewater treatment. Water-energy Interact Water Reuse, 2012, 161.
24. [24] Esa, S.K., Haque, A.A.M., Murshed, M., Performance of sewage oxidation pond in USM engineering campus. Awam international conference on civil engineering and geohazard information Zonation, Penang, 2012.
25. [25] Bhatt, N.C., Panwar, A., Bisht, T.S., Tamta, S., Coupling of algal biofuel production with wastewater. Sci World J, 2014, 2014, 210504.
26. [26] Kliopova, I., Makarskienė, K., Improving material and energy recovery from the sewage sludge and biomass residues. Waste Manage 36 (2015), 269–276.
27. [27] Mahapatra, D.M., Chanakya, H., Ramachandra, T., Euglena sp. as a suitable source of lipids for potential use as biofuel and sustainable wastewater treatment. J Appl Phycol 25 (2013), 855–865.
28. [28] Zainol, N.A., Aziz, H.A., Yusoff, M.S., Characterization of leachate from Kuala sepetang and Kulim landfills: a comparative study. Energy Environ Res 2 (2012), 45–52.
29. [29] Martins, C.L., Fernandes, H., Costa, R.H., Landfill leachate treatment as measured by nitrogen transformations in stabilization ponds. Bioresour Technol 147 (2013), 562–568.
30. [30] Zhao, X., Zhou, Y., Huang, S., Qiu, D., Schideman, L., Chai, X., et al. Characterization of microalgae-bacteria consortium cultured in landfill leachate for carbon fixation and lipid production. Bioresour Technol 156 (2014), 322–328.
31. [31] Jemec, A., Tišler, T., Žgajnar-Gotvajn, A., Assessment of landfill leachate toxicity reduction after biological treatment. Arch Environ Contam Toxicol 62 (2012), 210–221.
32. [32] Ogugua Nwuche, C., Chidimma Ekpo, D., Nwoye Eze, C., Aoyagi, H., Chukwuma Ogbonna, J., Use of palm oil mill effluent as medium for cultivation of Chlorella sorokiniana. Brit Biotechnol J 4 (2014), 305–316.
33. [33] Nur, M., Lipid extraction of microalga Chlorella sp. cultivated in palm oil mill effluent (POME) medium. World Appl Sci J 31 (2014), 959–967.
34. [34] Vairappan, C.S., Yen, A.M., Palm oil mill effluent (POME) cultured marine microalgae as supplementary diet for rotifer culture. J Appl Phycol 20 (2008), 603–608.
35. [35] Selmani, N., Mirghani, M.E., Alam, M.Z., Study the growth of microalgae in palm oil mill effluent waste water. IOP conference series: earth and environmental science, 2013, IOP Publishing.
36. [36] Cai, T., Park, S.Y., Li, Y., Nutrient recovery from wastewater streams by microalgae: status and prospects. Renew Sustain Energy Rev 19 (2013), 360–369.
37. [37] Subramaniam, R., Dufreche, S., Zappi, M., Bajpai, R., Microbial lipids from renewable resources: production and characterization. J Ind Microbiol Biotechnol 37 (2010), 1271–1287.
38. [38] Chen, C.-Y., Zhao, X.-Q., Yen, H.-W., Ho, S.-H., Cheng, C.-L., Lee, D.-J., et al. Microalgae-based carbohydrates for biofuel production. Biochem Eng J 78 (2013), 1–10.
39. [39] Ahmed, Y., Yaakob, Z., Akhtar, P., Sopian, K., Production of biogas and performance evaluation of existing treatment processes in palm oil mill effluent (POME). Renew Sustain Energy Rev 42 (2015), 1260–1278.
40. [40] Sydney, E., Da Silva, T., Tokarski, A., Novak, A., De Carvalho, J., Woiciecohwski, A., et al. Screening of microalgae with potential for biodiesel production and nutrient removal from treated domestic sewage. Appl Energy 88 (2011), 3291–3294.
41. 2-free biohydrogen production. Int J Hydrogen Energy 35 (2010), 10944–10953.
42. [42] Davis, R., Aden, A., Pienkos, P.T., Techno-economic analysis of autotrophic microalgae for fuel production. Appl Energy 88 (2011), 3524–3531.
43. [43] Yeh, K.-L., Chang, J.-S., Effects of cultivation conditions and media composition on cell growth and lipid productivity of indigenous microalga Chlorella vulgaris ESP-31. Bioresour Technol 105 (2012), 120–127.
44. [44] Chen, C.-Y., Yeh, K.-L., Aisyah, R., Lee, D.-J., Chang, J.-S., Cultivation, photobioreactor design and harvesting of microalgae for biodiesel production: a critical review. Bioresour Technol 102 (2011), 71–81.
45. [45] Yeh, K.-L., Chen, C.-Y., Chang, J.-S., PH-stat photoheterotrophic cultivation of indigenous Chlorella vulgaris ESP-31 for biomass and lipid production using acetic acid as the carbon source. Biochem Eng J 64 (2012), 1–7.
46. [46] Ramachandra, T., Durga Madhab, M., Shilpi, S., Joshi, N., Algal biofuel from urban wastewater in India: scope and challenges. Renew Sustain Energy Rev 21 (2013), 767–777.
47. [47] Gao, F., Yang, Z.H., Li, C., Wang, Y.J., Jin, W.H., Deng, Y.B., Concentrated microalgae cultivation in treated sewage by membrane photobioreactor operated in batch flow mode. Bioresour Technol 167 (2014), 441–446.
48. [48] de Souza Silva, A.P. Florentino, Costa, M.C., Colzi Lopes, A., Fares Abdala Neto, E., Carrhá Leitão, R., Mota, C.R., et al. Comparison of pretreatment methods for total lipids extraction from mixed microalgae. Renewable Energy 63 (2014), 762–766.
49. [49] Azarpira, P.B.H., Dhumal, K., Pondhe, G., Comparative studies on phycoremediation of sewage water by using blue green algae. Int J Biosci 4 (2014), 58–64.
50. [50] Makareviciene, V., Skorupskaite, V., Andruleviciute, V., Biodiesel fuel from microalgae-promising alternative fuel for the future: a review. Rev Environ Sci Bio/Technol 12 (2013), 119–130.
51. [51] Veeresh, M., Veeresh, A., Huddar, B.D., Hosetti, B.B., Dynamics of industrial waste stabilization pond treatment process. Environ Monit Assess 169 (2010), 55–65.
52. [52] Han, L., Pei, H., Hu, W., Jiang, L., Ma, G., Zhang, S., et al. Integrated campus sewage treatment and biomass production by Scenedesmus quadricauda SDEC-13. Bioresour Technol 175 (2015), 262–268.
53. [53] Mustafa, E.-M., Phang, S.-M., Chu, W.-L., Use of an algal consortium of five algae in the treatment of landfill leachate using the high-rate algal pond system. J Appl Phycol 24 (2012), 953–963.
54. [54] Edmundson, S.J., Wilkie, A.C., Landfill leachate – a water and nutrient resource for algae-based biofuels. Environ Technol 34 (2013), 1849–1857.
55. [55] Lin, L., Chan, G., Jiang, B., Lan, C., Use of ammoniacal nitrogen tolerant microalgae in landfill leachate treatment. Waste Manage 27 (2007), 1376–1382.
56. [56] Richards, R., Mullins, B., Modelling the kinetics of leachate remediation using microalgae. 19th international congress on modelling and simulation (MODSIM 2011), 2011, Modelling and Simulation Society of Australia, New Zealand.
57. [57] He, P., Mao, B., Shen, C., Shao, L., Lee, D., Chang, J., Cultivation of Chlorella vulgaris on wastewater containing high levels of ammonia for biodiesel production. Bioresour Technol 129 (2013), 177–181.
58. [58] Cheng, J., Ding, L., Xia, A., Lin, R., Li, Y., Zhou, J., et al. Hydrogen production using amino acids obtained by protein degradation in waste biomass by combined dark- and photo-fermentation. Bioresour Technol 179 (2015), 13–19.
59. [59] Illman, A., Scragg, A., Shales, S., Increase in Chlorella strains calorific values when grown in low nitrogen medium. Enzyme Microbial Technol 27 (2000), 631–635.
60. [60] Halfhide, T., Åkerstrøm, A., Lekang, O.I., Gislerød, H.R., Ergas, S.J., Production of algal biomass, chlorophyll, starch and lipids using aquaculture wastewater under axenic and non-axenic conditions. Algal Res 6 (2014), 152–159.
61. [61] Milledge, J.J., Heaven, S., A review of the harvesting of micro-algae for biofuel production. Rev Environ Sci Bio/Technol 12 (2013), 165–178.
62. [62] Rawat, I., Kumar, R.R., Mutanda, T., Bux, F., Dual role of microalgae: phycoremediation of domestic wastewater and biomass production for sustainable biofuels production. Appl Energy 88 (2011), 3411–3424.
63. 2 capture, wastewater treatment and biofuel production by microalgae culturing—a review. Renew Sustain Energy Rev 27 (2013), 622–653.
64. 2-emission mitigation systems—a review. Biotechnol Adv 29 (2011), 189–198.
65. [65] Pires, J., Alvim-Ferraz, M., Martins, F., Simões, M., Carbon dioxide capture from flue gases using microalgae: engineering aspects and biorefinery concept. Renew Sustain Energy Rev 16 (2012), 3043–3053.
66. [66] Lam, M.K., Lee, K.T., Microalgae biofuels: a critical review of issues, problems and the way forward. Biotechnol Adv 30 (2012), 673–690.
67. [67] Sivakumar, G., Xu, J., Thompson, R.W., Yang, Y., Randol-Smith, P., Weathers, P.J., Integrated green algal technology for bioremediation and biofuel. Bioresour Technol 107 (2012), 1–9.
68. [68] Saharan, B.S., Sharma, D., Sahu, R., Sahin, O., Warren, A., Towards algal biofuel production: a concept of green bio energy development. Innovat Rom Food Biotechnol 12 (2013), 1–21.
69. 2 fixation to biofuel production. Renew Sustain Energy Rev 15 (2011), 3252–3260.
70. [70] Holbrook, G.P., Davidson, Z., Tatara, R.A., Ziemer, N.L., Rosentrater, K.A., Grayburn, W.S., Use of the microalga Monoraphidium sp. grown in wastewater as a feedstock for biodiesel: cultivation and fuel characteristics. Appl Energy 131 (2014), 386–393.
71. [71] Liang, Y., Producing liquid transportation fuels from heterotrophic microalgae. Appl Energy 104 (2013), 860–868.
72. [72] DuPont, A., Best practices for the sustainable production of algae-based biofuel in China. Mitig Adapt Strat Glob Change 18 (2013), 97–111.
73. [73] Hernández, D., Riaño, B., Coca, M., García-González, M.C., Saccharification of carbohydrates in microalgal biomass by physical, chemical and enzymatic pre-treatments as a previous step for bioethanol production. Chem Eng J 262 (2015), 939–945.
74. [74] Suali, E., Sarbatly, R., Conversion of microalgae to biofuel. Renew Sustain Energy Rev 16 (2012), 4316–4342.
75. [75] Huang, H.-J., Ramaswamy, S., Liu, Y., Separation and purification of biobutanol during bioconversion of biomass. Sep Purif Technol 132 (2014), 513–540.
76. [76] Jones, C.S., Mayfield, S.P., Algae biofuels: versatility for the future of bioenergy. Curr Opin Biotechnol 23 (2012), 346–351.
77. [77] Ho, S.-H., Huang, S.-W., Chen, C.-Y., Hasunuma, T., Kondo, A., Chang, J.-S., Bioethanol production using carbohydrate-rich microalgae biomass as feedstock. Bioresour Technol 135 (2013), 191–198.
78. [78] Costa, J.A.V., De Morais, M.G., The role of biochemical engineering in the production of biofuels from microalgae. Bioresour Technol 102 (2011), 2–9.
79. [79] Daroch, M., Geng, S., Wang, G., Recent advances in liquid biofuel production from algal feedstocks. Appl Energy 102 (2013), 1371–1381.
80. 2 fixation and lipid/carbohydrate production of an indigenous microalga Scenedesmus obliquus CNW-N. Bioresour Technol 113 (2012), 244–252.
81. 2 fixation and carbohydrate productivity of Scenedesmus obliquus CNW-N used for bioethanol fermentation. Bioresour Technol 143 (2013), 163–171.
82. [82] Ho, S.-H., Huang, S.-W., Chen, C.-Y., Hasunuma, T., Kondo, A., Chang, J.-S., Characterization and optimization of carbohydrate production from an indigenous microalga Chlorella vulgaris FSP-E. Bioresour Technol 135 (2013), 157–165.
83. [83] Dragone, G., Fernandes, B.D., Abreu, A.P., Vicente, A.A., Teixeira, J.A., Nutrient limitation as a strategy for increasing starch accumulation in microalgae. Appl Energy 88 (2011), 3331–3335.
84. [84] Yao, C., Ai, J., Cao, X., Xue, S., Zhang, W., Enhancing starch production of a marine green microalga Tetraselmis subcordiformis through nutrient limitation. Bioresour Technol 118 (2012), 438–444.
85. [85] Choix, F.J., de-Bashan, L.E., Bashan, Y., Enhanced accumulation of starch and total carbohydrates in alginate-immobilized Chlorella spp. induced by Azospirillum brasilense: II. Heterotrophic conditions. Enzyme Microbial Technol, 51, 2012.
86. [86] Harun, R., Danquah, M.K., Forde, G.M., Microalgal biomass as a fermentation feedstock for bioethanol production. J Chem Technol Biotechnol 85 (2009), 199–203.
87. [87] Harun, R., Danquah, M.K., Enzymatic hydrolysis of microalgal biomass for bioethanol production. Chem Eng J 168 (2011), 1079–1084.
88. [88] Castro, Y.A., Ellis, J.T., Miller, C.D., Sims, R.C., Optimization of wastewater microalgae saccharification using dilute acid hydrolysis for acetone, butanol, and ethanol fermentation. Appl Energy 140 (2015), 14–19.
89. [89] Cheng, H.-H., Whang, L.-M., Chan, K.-C., Chung, M.-C., Wu, S.-H., Liu, C.-P., et al. Biological butanol production from microalgae-based biodiesel residues by Clostridium acetobutylicum. Bioresour Technol 184 (2015), 379–385.
90. [90] Chow, T.-J., Su, H.-Y., Tsai, T.-Y., Chou, H.-H., Lee, T.-M., Chang, J.-S., Using recombinant cyanobacterium (Synechococcus elongatus) with increased carbohydrate productivity as feedstock for bioethanol production via separate hydrolysis and fermentation process. Bioresour Technol 184 (2014), 33–41.
91. [91] Harun, R., Singh, M., Forde, G.M., Danquah, M.K., Bioprocess engineering of microalgae to produce a variety of consumer products. Renew Sustain Energy Rev 14 (2010), 1037–1047.
92. [92] Brennan, L., Owende, P., Biofuels from microalgae—a review of technologies for production, processing, and extractions of biofuels and co-products. Renew Sustain Energy Rev 14 (2010), 557–577.
93. [93] Harun, R., Liu, B., Danquah, M.K., Analysis of process configurations for bioethanol production from microalgal biomass. Progress in biomass and bioenergy production, 2011, Intech Science, Technology & Medicine, Croatia, 395–408 [ISBN].
94. [94] Pragya, N., Pandey, K.K., Sahoo, P., A review on harvesting, oil extraction and biofuels production technologies from microalgae. Renew Sustain Energy Rev 24 (2013), 159–171.
95. [95] Costa, R.L., Oliveira, T.V., de Souza Ferreira, J., Cardoso, V.L., Batista, F.R.X., Prospective technology on bioethanol production from photofermentation. Bioresour Technol 181 (2015), 330–337.
96. [96] Hamed, S.R., Complementary production of biofuels by the green alga Chlorella vulgaris. Int J Renew Energy Res 5 (2015), 936–943.
97. [97] Choi, S.P., Nguyen, M.T., Sim, S.J., Enzymatic pretreatment of Chlamydomonas reinhardtii biomass for ethanol production. Bioresour Technol 101 (2010), 5330–5336.
98. [98] Diaz, J.T., Chinn, M.S., Truong, V.-D., Simultaneous saccharification and fermentation of industrial sweetpotatoes for ethanol production and anthocyanins extraction. Ind Crops Prod 62 (2014), 53–60.
99. [99] Kim, N.-J., Li, H., Jung, K., Chang, H.N., Lee, P.C., Ethanol production from marine algal hydrolysates using Escherichia coli KO11. Bioresour Technol 102 (2011), 7466–7469.
100. [100] Kim, J.K., Um, B.-H., Kim, T.H., Bioethanol production from micro-algae, Schizocytrium sp., using hydrothermal treatment and biological conversion. Korean J Chem Eng 29 (2012), 209–214.
101. [101] Wirawan, F., Cheng, C.-L., Kao, W.-C., Lee, D.-J., Chang, J.-S., Cellulosic ethanol production performance with SSF and SHF processes using immobilized Zymomonas mobilis. Appl Energy 100 (2012), 19–26.
102. [102] Singh, J., Gu, S., Commercialization potential of microalgae for biofuels production. Renew Sustain Energy Rev 14 (2010), 2596–2610.
103. [103] Hirayama, S., Ethanol production from carbon dioxide by fermentative microalgae. Stud Surf Sci Catal 114 (1986), 657–660.
104. [104] Wen, Z., Liu, J., Chen, F., Biofuel from microalgae. Murray, M.-Y., (eds.) Comprehensive biotechnology, 2011, Academic Press, Burlington [Chapter 3.12].
105. [105] Jones, D.T., David, R., Acetone-Butanol fermentation revisited. Microbiol Rev 50 (1986), 484–524.
106. [106] Tsai, T.-Y., Lo, Y.-C., Chang, J.-S., Effect of medium composition and pH control strategies on butanol fermentation with Clostridium Acetobutylicum. Energy Proc 61 (2014), 1691–1694.
107. [107] Wang, Y., Guo, W.Q., Chang, J.S., Ren, N.Q., Butanol production using carbohydrate-enriched Chlorella vulgaris as feedstock. Adv Mater Res 830 (2014), 122–125.
108. 4 using sequential glucose–glycerol addition and simultaneous dual-substrate cultivation strategies. Bioresour Technol 135 (2013), 324–330.
109. [109] Xia, A., Cheng, J., Lin, R., Lu, H., Zhou, J., Cen, K., Comparison in dark hydrogen fermentation followed by photo hydrogen fermentation and methanogenesis between protein and carbohydrate compositions in Nannochloropsis oceanica biomass. Bioresour Technol 138 (2013), 204–213.
110. [110] Kawaguchi, H., Hashimoto, K., Hirata, K., Miyamoto, K., H 2 production from algal biomass by a mixed culture of Rhodobium marinum A-501 and Lactobacillus amylovorus. J Biosci Bioeng 91 (2001), 277–282.
111. [111] Liu, C.-H., Chang, C.-Y., Liao, Q., Zhu, X., Liao, C.-F., Chang, J.-S., Biohydrogen production by a novel integration of dark fermentation and mixotrophic microalgae cultivation. Int J Hydrogen Energy 38 (2013), 15807–15814.
112. [112] Efremenko, E., Nikolskaya, A., Lyagin, I., Senko, O., Makhlis, T., Stepanov, N., et al. Production of biofuels from pretreated microalgae biomass by anaerobic fermentation with immobilized Clostridium acetobutylicum cells. Bioresour Technol 114 (2012), 342–348.
113. [113] Wong, Y.M., Wu, T.Y., Juan, J.C., A review of sustainable hydrogen production using seed sludge via dark fermentation. Renew Sustain Energy Rev 34 (2014), 471–482.
114. [114] Frigon, J.-C., Matteau-Lebrun, F., Abdou, R.H., McGinn, P.J., O'Leary, S.J., Guiot, S.R., Screening microalgae strains for their productivity in methane following anaerobic digestion. Appl Energy 108 (2013), 100–107.
115. 2. Appl Energy 88 (2011), 3336–3341.
116. 2 fixation with Spirulina platensis. Bioresour Technol 145 (2013), 307–312.
117. [117] Yen, H.-W., Hu, I.-C., Chen, C.-Y., Ho, S.-H., Lee, D.-J., Chang, J.-S., Microalgae-based biorefinery–from biofuels to natural products. Bioresour Technol 135 (2013), 166–174.
118. 2 by microalgae. Bioresour Technol 184 (2015), 190–201.
119. 2-emission mitigation systems—a review. Biotechnol Adv 29 (2011), 189–198.
120. [120] Lam, M.K., Lee, K.T., Potential of using organic fertilizer to cultivate Chlorella vulgaris for biodiesel production. Appl Energy 94 (2012), 303–308.
121. [121] Tang, H., Abunasser, N., Garcia, M., Chen, M., Ng, K.S., Salley, S.O., Potential of microalgae oil from Dunaliella tertiolecta as a feedstock for biodiesel. Appl Energy 88 (2011), 3324–3330.
122. [122] Zhu, L., Hiltunen, E., Shu, Q., Zhou, W., Li, Z., Wang, Z., Biodiesel production from algae cultivated in winter with artificial wastewater through pH regulation by acetic acid. Appl Energy 128 (2014), 103–110.
123. [123] Cai, T., Park, S.Y., Racharaks, R., Li, Y., Cultivation of Nannochloropsis salina using anaerobic digestion effluent as a nutrient source for biofuel production. Appl Energy 108 (2013), 486–492.
124. [124] Ribeiro, L.A., da Silva, P.P., Surveying techno-economic indicators of microalgae biofuel technologies. Renew Sustain Energy Rev 25 (2013), 89–96.
125. [125] Brányiková, I., Maršálková, B., Doucha, J., Brányik, T., Bišová, K., Zachleder, V., et al. Microalgae—novel highly efficient starch producers. Biotechnol Bioeng 108 (2011), 766–776.
126. 2 fixation and ethanol production with microalgal photosynthesis and intracellular anaerobic fermentation. Energy 22 (1997), 137–142.
127. [127] Sydney, E.B., Sturm, W., de Carvalho, J.C., Thomaz-Soccol, V., Larroche, C., Pandey, A., et al. Potential carbon dioxide fixation by industrially important microalgae. Bioresour Technol 101 (2010), 5892–5896.
128. [128] Brown, M.R., McCausland, M.A., Kowalski, K., The nutritional value of four Australian microalgal strains fed to Pacific oyster Crassostrea gigas spat. Aquaculture 165 (1998), 281–293.
129. [129] Kim, M.-S., Baek, J.-S., Yun, Y.-S., Sim, S.J., Park, S., Kim, S.-C., Hydrogen production from Chlamydomonas reinhardtii biomass using a two-step conversion process: anaerobic conversion and photosynthetic fermentation. Int J Hydrogen Energy 31 (2006), 812–816.