[1]. Haitao, R., F. GUO and X. Yang, Potential production of microalgae bio-jet fuel and CO2 emissions
reduction in China. Journal of Beijing University of Aeronautics and Astronautics, 2016. 42(5): p. 912-919.
[2]. Eloka-Eboka, A.C. and F.L. Inambao, Effects of CO2 sequestration on lipid and biomass productivity in microalgal biomass production. Applied Energy, 2017. 195: p. 1100-1111.
[3]. Barr, W.J. and A.E. Landis, Comparative life cycle assessment of a commercial algal multiproduct biorefinery and wild caught fishery for small pelagic fish. The International Journal of Life Cycle Assessment, 2018. 23(5): p. 1141-1150.
[4]. Bahadar, A. and M. Bilal Khan, Progress in energy from microalgae: A review. Renewable and Sustainable Energy Reviews, 2013. 27: p. 128-148.
[5]. Sati, H., et al., Microalgal lipid extraction strategies for biodiesel production: A review. Algal Research, 2019. 38: p. 101413.
[6]. Menegazzo, M.L. and G.G. Fonseca, Biomass recovery and lipid extraction processes for microalgae biofuels production: A review. Renewable and Sustainable Energy Reviews, 2019. 107: p. 87-107.
[7]. Sudhakar, M.P., et al., A review on bioenergy and bioactive compounds from microalgae and macroalgae-sustainable energy perspective. Journal of Cleaner Production, 2019. 228: p. 1320-1333.
[8]. Pierobon, S.C., et al., Emerging microalgae technology: a review. Sustainable Energy & Fuels, 2018. 2(1): p. 13-38.
[9]. Cheah, W.Y., et al., Biosequestration of atmospheric CO2 and flue gas-containing CO2 by microalgae. Bioresource Technology, 2015. 184: p. 190-201.
[10]. Chen, C., et al., Engineering strategies for enhancing the production of eicosapentaenoic acid (EPA) from an isolated microalga Nannochloropsis oceanica CY2. Bioresource Technology, 2013. 147: p. 160-167.
[11]. Meng, Y., et al., The characteristics of TAG and EPA accumulation in Nannochloropsis oceanica IMET1 under different nitrogen supply regimes. Bioresource Technology, 2015. 179: p. 483-489.
[12]. Mobin, S.M.A., H. Chowdhury and F. Alam, Commercially important bioproducts from microalgae and their current applications – A review. Energy Procedia, 2019. 160: p. 752-760.
[13]. Madeira, M.S., et al., Microalgae as feed ingredients for livestock production and meat quality: A review. Livestock Science, 2017. 205: p. 111-121.
[14]. Vaz, B.D.S., et al., Microalgae as a new source of bioactive compounds in food supplements. Current Opinion in Food Science, 2016. 7: p. 73-77.
[15]. Liu, Z. and X. Yang, Refining drop-in jet fuel coupling GHGs reduction in LCA with airworthiness in aero-engine and aircraft. Catalysis Today, 2018.
[16]. Tang, S., et al., Hydrotreatment of biocrudes derived from hydrothermal liquefaction and lipid extraction of the high-lipid Scenedesmus. Green Chemistry, 2019. 21(12): p. 3413-3423.
[17]. Liaw, B., et al., Net energy and greenhouse gas emission evaluation of biodiesel derived from microalgae. Environmental Science & Technology, 2010. 44(20): p. 7975-7980.
[18]. Clarens, A.F., et al., Environmental impacts of algae-derived biodiesel and bioelectricity for transportation. Environmental Science & Technology, 2011. 45(17): p. 7554-7560.
[19]. Morales, M., A. Hélias and O. Bernard, Optimal integration of microalgae production with photovoltaic panels: environmental impacts and energy balance. Biotechnology for Biofuels, 2019. 12(1): p. 239.
[20]. Sun, C., et al., Life-cycle assessment of biofuel production from microalgae via various bioenergy conversion systems. Energy, 2019. 171: p. 1033-1045.
[21]. Shi, R., R.M. Handler and D.R. Shonnard, Life cycle assessment of novel technologies for algae harvesting and oil extraction in the renewable diesel pathway. Algal Research, 2019. 37: p. 248-259.
[22]. Sun, C., et al., Life-cycle assessment of biofuel production from microalgae via various bioenergy conversion systems. Energy, 2019. 171: p. 1033-1045.
[23]. Schneider, R.D.C.D., et al., Life cycle assessment of microalgae production in a raceway pond with alternative culture media. Algal Research, 2018. 32: p. 280-292.
[24]. Wang, X., et al., Effect of pretreatment on microalgae pyrolysis: Kinetics, biocrude yield and quality, and life cycle assessment. Energy Conversion and Management, 2017. 132: p. 161-171.
[25]. Guo, F., et al., Life cycle assessment of microalgae-based aviation fuel: Influence of lipid content with specific productivity and nitrogen nutrient effects. Bioresource Technology, 2016. 221: p. 350-357.
[26]. Pierobon, F., I.L. Eastin and I. Ganguly, Life cycle assessment of residual lignocellulosic biomass-based jet fuel with activated carbon and lignosulfonate as co-products. Biotechnology for Biofuels, 2018. 11(1): p. 139.
[27]. Lardon, L., et al., Life-Cycle Assessment of Biodiesel Production from Microalgae. Environmental Science & Technology, 2009. 43(17): p. 6475-6481.
[28]. Yang, X., et al., Carbon distribution of algae-based alternative aviation fuel obtained by different pathways. Renewable and Sustainable Energy Reviews, 2016. 54: p. 1129-1147.
[29]. Wang, X., L. Sheng and X. Yang, Pyrolysis characteristics and pathways of protein, lipid and carbohydrate isolated from microalgae Nannochloropsis sp. Bioresource Technology, 2017. 229: p. 119-125.
[30]. Ho, S., et al., Perspectives on microalgal CO2-emission mitigation systems — A review. Biotechnology Advances, 2011. 29(2): p. 189-198.
[31]. Van Den Hende, S., H. Vervaeren and N. Boon, Flue gas compounds and microalgae: (Bio-)chemical interactions leading to biotechnological opportunities. Biotechnology Advances, 2012. 30(6): p. 1405-1424.
[32]. Wang, M., et al., Post-combustion CO2 capture with chemical absorption: A state-of-the-art review. Chemical Engineering Research and Design, 2011. 89(9): p. 1609-1624.
[33]. Pires, J.C.M., et al., Recent developments on carbon capture and storage: An overview. Chemical Engineering Research and Design, 2011. 89(9): p. 1446-1460.
[34]. Khoo, H.H. and R.B.H. Tan, Life Cycle Investigation of CO2 Recovery and Sequestration. Environmental Science & Technology, 2006. 40(12): p. 4016-4024.
[35]. Siagian, U.W.R., et al., Membrane-based carbon capture technologies: Membrane gas separation vs. membrane contactor. Journal of Natural Gas Science and Engineering, 2019. 67: p. 172-195.
[36]. Abbas, Z., T. Mezher and M.R.M. Abu-Zahra, CO2 purification. Part I: Purification requirement review and the selection of impurities deep removal technologies. International Journal of Greenhouse Gas Control, 2013. 16: p. 324-334.
[37]. Bahadar, A. and M. Bilal Khan, Progress in energy from microalgae: A review. Renewable and Sustainable Energy Reviews, 2013. 27: p. 128-148.
[38]. Ra, C., et al., Effects of light-emitting diodes (LEDs) on the accumulation of lipid content using a two-phase culture process with three microalgae. Bioresource Technology, 2016. 212: p. 254-261.
[39]. Wan, C., F. Bai and X. Zhao, Effects of nitrogen concentration and media replacement on cell growth and lipid production of oleaginous marine microalga Nannochloropsis oceanica DUT01. Biochemical Engineering Journal, 2013. 78: p. 32-38.
[40]. Chen, C., et al., Engineering strategies for enhancing the production of eicosapentaenoic acid (EPA) from an isolated microalga Nannochloropsis oceanica CY2. Bioresource Technology, 2013. 147: p. 160-167.
[41]. Kurpan Nogueira, D.P., et al., Impact of temperature and light intensity on triacylglycerol accumulation in marine microalgae. Biomass and Bioenergy, 2015. 72: p. 280-287.
[42]. Yoo, G., et al., Lipid content in microalgae determines the quality of biocrude and Energy Return On Investment of hydrothermal liquefaction. Applied Energy, 2015. 156: p. 354-361.
[43]. Meng, Y., et al., The characteristics of TAG and EPA accumulation in Nannochloropsis oceanica IMET1 under different nitrogen supply regimes. Bioresource Technology, 2015. 179: p. 483-489.
[44]. Eloka-Eboka, A.C. and F.L. Inambao, Effects of CO2 sequestration on lipid and biomass productivity in microalgal biomass production. Applied Energy, 2017. 195: p. 1100-1111.
[45]. Shi, Z., et al., Hydrotreating lipids for aviation biofuels derived from extraction of wet and dry algae. Journal of Cleaner Production, 2018. 204: p. 906-915.
[46]. Zhao, B., et al., Two-stage upgrading of hydrothermal algae biocrude to kerosene-range biofuel. Green Chemistry, 2016. 18(19): p. 5254-5265.
[47]. Zhao, B., Z. Shi and X. Yang, Upgrading Algae Biocrude for Low N-containing Biofuel: Compositions, Intermediate and Reaction Routes. Industrial & Engineering Chemistry Research, 2017. 56(22).