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Prospects for methane production and nutrient recycling from lipid extracted residues and whole Nannochloropsis salina using anaerobic digestion

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  • Bohutskyi, Pavlo
  • Chow, Steven
  • Ketter, Ben
  • Betenbaugh, Michael J.
  • Bouwer, Edward J.

Abstract

Sustainable mass production of algal biofuels requires a reduction in nutrient demand and efficient conversion into fuels of all biomass including lipid-extracted algal residues (LEA). This study evaluated methane production, nutrient recovery and recycling from untreated and enzymatically pretreated Nannochloropsis LEA using semi-continuous anaerobic digestion (AD). Additionally, this process was compared to methane generation from whole Nannochloropsis alga (WA) and thermally pretreated WA. The methane production from untreated LEA and WA reached up to 0.22L and 0.24L per gram of biomass volatile solids (VS), respectively, corresponding to only 36–38% of the theoretical potential. Additionally, observed VS reduction was only 40–50% confirming biomass recalcitrance to biodegradation. While enzymatic treatment hydrolyzed up to 65% of the LEA polysaccharides, the methane production increased by only 15%. Alternatively, WA thermal pretreatment at 150–170°C enhanced methane production up to 40%. Overall, an integrated process of lipid conversion into biodiesel coupled with LEA conversion into methane generates nearly 40% more energy compared to methane production from WA, and about 100% more energy than from biodiesel alone. Additionally, the AD effluent contained up to 60–70% of the LEA phosphorus content, 30–50% of the nitrogen, sulfur, calcium and boron, 20% of the iron and cobalt, and 10% of manganese, zinc and copper, which can partially replace chemical fertilizers during algal cultivation. Consequently, supplementation of Nannochloropsis cultures with 5% AD effluent was optimal for a high algal growth rate. Therefore, coupling biodiesel and methane production provides significant energy advantages along with sustainability and economic benefits from nutrient recycling.

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  • Bohutskyi, Pavlo & Chow, Steven & Ketter, Ben & Betenbaugh, Michael J. & Bouwer, Edward J., 2015. "Prospects for methane production and nutrient recycling from lipid extracted residues and whole Nannochloropsis salina using anaerobic digestion," Applied Energy, Elsevier, vol. 154(C), pages 718-731.
    • Handle: RePEc:eee:appene:v:154:y:2015:i:c:p:718-731
    DOI: 10.1016/j.apenergy.2015.05.069
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    2. Barbera, Elena & Bertucco, Alberto & Kumar, Sandeep, 2018. "Nutrients recovery and recycling in algae processing for biofuels production," Renewable and Sustainable Energy Reviews, Elsevier, vol. 90(C), pages 28-42.
    3. Di Maria, Francesco & Micale, Caterina & Contini, Stefano, 2016. "Energetic and environmental sustainability of the co-digestion of sludge with bio-waste in a life cycle perspective," Applied Energy, Elsevier, vol. 171(C), pages 67-76.
    4. Xu, Xianzhen & Gu, Xiaoguang & Wang, Zhongyang & Shatner, William & Wang, Zhenjun, 2019. "Progress, challenges and solutions of research on photosynthetic carbon sequestration efficiency of microalgae," Renewable and Sustainable Energy Reviews, Elsevier, vol. 110(C), pages 65-82.
    5. Ayala-Parra, Pedro & Liu, Yuanzhe & Field, Jim A. & Sierra-Alvarez, Reyes, 2017. "Nutrient recovery and biogas generation from the anaerobic digestion of waste biomass from algal biofuel production," Renewable Energy, Elsevier, vol. 108(C), pages 410-416.
    6. Moon, Myounghoon & Park, Won-Kun & Lee, Soo Youn & Hwang, Kyung-Ran & Lee, Sangmin & Kim, Min-Sik & Kim, Bolam & Oh, You-Kwan & Lee, Jin-Suk, 2022. "Utilization of whole microalgal biomass for advanced biofuel and biorefinery applications," Renewable and Sustainable Energy Reviews, Elsevier, vol. 160(C).
    7. Zhang, Yi & Kang, Xihui & Wang, Zhongming & Kong, Xiaoying & Li, Lianhua & Sun, Yongming & Zhu, Shunni & Feng, Siran & Luo, Xinjian & Lv, Pengmei, 2018. "Enhancement of the energy yield from microalgae via enzymatic pretreatment and anaerobic co-digestion," Energy, Elsevier, vol. 164(C), pages 400-407.
    8. Chen, Yimin & Xu, Changan & Vaidyanathan, Seetharaman, 2020. "Influence of gas management on biochemical conversion of CO2 by microalgae for biofuel production," Applied Energy, Elsevier, vol. 261(C).
    9. Lee, Jongkeun & Lee, Kwanyong & Sohn, Donghwan & Kim, Young Mo & Park, Ki Young, 2018. "Hydrothermal carbonization of lipid extracted algae for hydrochar production and feasibility of using hydrochar as a solid fuel," Energy, Elsevier, vol. 153(C), pages 913-920.
    10. Brigagão, George Victor & Wiesberg, Igor Lapenda & Pinto, Juliana Leite & Araújo, Ofélia de Queiroz Fernandes & de Medeiros, José Luiz, 2019. "Upstream and downstream processing of microalgal biogas: Emissions, energy and economic performances under carbon taxation," Renewable and Sustainable Energy Reviews, Elsevier, vol. 112(C), pages 508-520.
    11. Calixto, Clediana Dantas & da Silva Santana, Jordana Kaline & Tibúrcio, Viviane Pereira & de Pontes, Liliana de Fátima Bezerra Lira & da Costa Sassi, Cristiane Francisca & da Conceição, Marta Maria & , 2018. "Productivity and fuel quality parameters of lipids obtained from 12 species of microalgae from the northeastern region of Brazil," Renewable Energy, Elsevier, vol. 115(C), pages 1144-1152.

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