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Effects of CO2 sequestration on lipid and biomass productivity in microalgal biomass production

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  • Eloka-Eboka, Andrew C.
  • Inambao, Freddie L.

Abstract

The study is focused on the technology and manipulation of production strategies for the cultivation of biomass from four strains of microalgae. Species of microalgae studied are: Chlorella vulgaris, Dunaliella, Scenedesmus quadricauda and Synechococcus spp. The effects of the rate and amount of CO2 removal from the atmosphere and sequestration with dissolved oxygen on lipid production from accumulated biomass were studied. Also, the rate of sequestration of both total and dissolved carbon was investigated. Daily measurements of total, organic and inorganic carbon sequestrated, optical densities, proximate analysis and kinetic parameters of the growing and cultivated microalga were monitored and carried out during the two phases of cultivation: dark and light phases. The values of maximum rate of carbon (IV) oxide removed, rmax varied from 11.73mgL−1min−1 to 18.84mgL−1min−1 from Chlorella vulgaris to Synechoccocus spp. Important parameters such as biomass productivity, maximum pH values obtained at cultivation, lipid content of the produced biomass and the hydraulic detection time for all four strains of microalgae were considered and presented in comparison and with their individual and collective effects. The ratios of the rate of CO2 absorption constant and the constant for the CO2 desorption rate (k1/k2) occurred highest in Dunaliella suggesting that with a high uptake of CO2, the algal strain is more effective in CO2 sequestration. The best biomass producer in this study was the C. vulgaris (Xmax=5400mgL−1 and Px=35.1mgLh−1) where biomass productivity is Px and the maximum cellular concentration is Xmax. C. vulgaris has the highest lipids productivity of 27% while Synechoccocus has the least (11.72%). In general, biomass productivity may be inversely related; this fact may be explained by greater metabolic involvement of lipid biosynthesis. This pioneer study may be advanced further to developing models for strategic manipulation and optimisation approach in micro algal biomass cultivation.

Suggested Citation

  • Eloka-Eboka, Andrew C. & Inambao, Freddie L., 2017. "Effects of CO2 sequestration on lipid and biomass productivity in microalgal biomass production," Applied Energy, Elsevier, vol. 195(C), pages 1100-1111.
    • Handle: RePEc:eee:appene:v:195:y:2017:i:c:p:1100-1111
    DOI: 10.1016/j.apenergy.2017.03.071
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    References listed on IDEAS

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    2. Lim, Jackson Hwa Keen & Gan, Yong Yang & Ong, Hwai Chyuan & Lau, Beng Fye & Chen, Wei-Hsin & Chong, Cheng Tung & Ling, Tau Chuan & Klemeš, Jiří Jaromír, 2021. "Utilization of microalgae for bio-jet fuel production in the aviation sector: Challenges and perspective," Renewable and Sustainable Energy Reviews, Elsevier, vol. 149(C).
    3. Jung, Sungyup & Kim, Jung-Hun & Jeon, Young Jae & Park, Young-Kwon & Kwon, Eilhann E., 2020. "Synergistic use of carbon dioxide in catalytic pyrolysis of chlorella vulgaris over Ni and Co catalysts," Energy, Elsevier, vol. 211(C).
    4. Zhang, Xinghua & Tang, Wenwu & Zhang, Qi & Wang, Tiejun & Ma, Longlong, 2018. "Hydrodeoxygenation of lignin-derived phenoic compounds to hydrocarbon fuel over supported Ni-based catalysts," Applied Energy, Elsevier, vol. 227(C), pages 73-79.
    5. Lim, Yi An & Chong, Meng Nan & Foo, Su Chern & Ilankoon, I.M.S.K., 2021. "Analysis of direct and indirect quantification methods of CO2 fixation via microalgae cultivation in photobioreactors: A critical review," Renewable and Sustainable Energy Reviews, Elsevier, vol. 137(C).
    6. Li, Ming & Zhou, Minghua & Tian, Xiaoyu & Tan, Chaolin & Gu, Tingyue, 2021. "Enhanced bioenergy recovery and nutrient removal from swine wastewater using an airlift-type photosynthetic microbial fuel cell," Energy, Elsevier, vol. 226(C).
    7. Song, Chunfeng & Xie, Meilian & Qiu, Yiting & Liu, Qingling & Sun, Luchang & Wang, Kailiang & Kansha, Yasuki, 2019. "Integration of CO2 absorption with biological transformation via using rich ammonia solution as a nutrient source for microalgae cultivation," Energy, Elsevier, vol. 179(C), pages 618-627.
    8. Li, Wei & Lu, Can & Ding, Yi & Zhang, Yan-Wu, 2017. "The impacts of policy mix for resolving overcapacity in heavy chemical industry and operating national carbon emission trading market in China," Applied Energy, Elsevier, vol. 204(C), pages 509-524.
    9. Andrew Eloka-Eboka & Chiemela Onunka & Freddie Inambao, 2018. "Detailed design and optimization of a sustainable micro-algal biofuel process plant," International Journal of Low-Carbon Technologies, Oxford University Press, vol. 13(2), pages 122-130.
    10. Yang, Qiulian & Li, Haitao & Wang, Dong & Zhang, Xiaochun & Guo, Xiangqian & Pu, Shaochen & Guo, Ruixin & Chen, Jianqiu, 2020. "Utilization of chemical wastewater for CO2 emission reduction: Purified terephthalic acid (PTA) wastewater-mediated culture of microalgae for CO2 bio-capture," Applied Energy, Elsevier, vol. 276(C).
    11. Fasahati, Peyman & Wu, Wenzhao & Maravelias, Christos T., 2019. "Process synthesis and economic analysis of cyanobacteria biorefineries: A superstructure-based approach," Applied Energy, Elsevier, vol. 253(C), pages 1-1.

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