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Feasibility of acetone–butanol–ethanol fermentation from eucalyptus hydrolysate without nutrients supplementation

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  • Zheng, Jin
  • Tashiro, Yukihiro
  • Wang, Qunhui
  • Sakai, Kenji
  • Sonomoto, Kenji

Abstract

The economic feasibility of acetone–butanol–ethanol (ABE) fermentation is greatly affected by the type of raw material used. The easy availability of eucalyptus from marginal environments is an alternative feedstock for use as raw material to reduce the production cost. In this study, hydrolyzed eucalyptus was used for ABE production without any nutrients supplementation. Increasing the solid concentration in the eucalyptus slurry from 6.7% (w-dry matter/v) to 25% led to an increase in the initial glucose concentration from 33.7g/L to 86.7g/L after enzymatic hydrolysis. Dosed cellulases not only hydrolyzed cellulose but also supplied nitrogen source for ABE producing strain. However, ABE production from the obtained hydrolysate decreased when the solid concentration was increased to more than 10%. The maximum ABE of 12.3g/L was obtained at 10% solid concentration, with an initial glucose concentration of approximately 40g/L. In addition, the fermentation capability of eucalyptus hydrolysate was found to be improved by diluting the hydrolysate, which prevented inhibition by substrate and fermentation inhibitors. Finally, ABE concentration was improved to 13.1g/L by diluting the hydrolysate from the initial solid concentration of 25% to an initial glucose concentration of 45g/L, which resulted in ABE productivity of 0.109g/L/h and ABE yield of 0.413g/g. Thus, the high ABE production from eucalyptus makes it a potential feedstock for biofuel production.

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  • Zheng, Jin & Tashiro, Yukihiro & Wang, Qunhui & Sakai, Kenji & Sonomoto, Kenji, 2015. "Feasibility of acetone–butanol–ethanol fermentation from eucalyptus hydrolysate without nutrients supplementation," Applied Energy, Elsevier, vol. 140(C), pages 113-119.
    • Handle: RePEc:eee:appene:v:140:y:2015:i:c:p:113-119
    DOI: 10.1016/j.apenergy.2014.11.037
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    2. Pereira, L.G. & Dias, M.O.S. & Mariano, A.P. & Maciel Filho, R. & Bonomi, A., 2015. "Economic and environmental assessment of n-butanol production in an integrated first and second generation sugarcane biorefinery: Fermentative versus catalytic routes," Applied Energy, Elsevier, vol. 160(C), pages 120-131.
    3. Wang, Pixiang & Chen, Yong Mei & Wang, Yifen & Lee, Yoon Y. & Zong, Wenming & Taylor, Steven & McDonald, Timothy & Wang, Yi, 2019. "Towards comprehensive lignocellulosic biomass utilization for bioenergy production: Efficient biobutanol production from acetic acid pretreated switchgrass with Clostridium saccharoperbutylacetonicum ," Applied Energy, Elsevier, vol. 236(C), pages 551-559.
    4. Su, Changsheng & Zhang, Changwei & Wu, Yilu & Zhu, Qian & Wen, Jieyi & Wang, Yankun & Zhao, Jianbo & Liu, Yicheng & Qin, Peiyong & Cai, Di, 2022. "Combination of pH adjusting and intermittent feeding can improve fermentative acetone-butanol-ethanol (ABE) production from steam exploded corn stover," Renewable Energy, Elsevier, vol. 200(C), pages 592-600.
    5. Luo, Wei & Zhao, Zhangmin & Pan, Hepeng & Zhao, Lankun & Xu, Chuangao & Yu, Xiaobin, 2018. "Feasibility of butanol production from wheat starch wastewater by Clostridium acetobutylicum," Energy, Elsevier, vol. 154(C), pages 240-248.
    6. Zhu, Ming-Qiang & Wen, Jia-Long & Wang, Zhi-Wen & Su, Yin-Quan & Wei, Qin & Sun, Run-Cang, 2015. "Structural changes in lignin during integrated process of steam explosion followed by alkaline hydrogen peroxide of Eucommia ulmoides Oliver and its effect on enzymatic hydrolysis," Applied Energy, Elsevier, vol. 158(C), pages 233-242.
    7. Zheng, Jin & Tashiro, Yukihiro & Zhao, Tao & Wang, Qunhui & Sakai, Kenji & Sonomoto, Kenji, 2017. "Enhancement of acetone-butanol-ethanol fermentation from eucalyptus hydrolysate with optimized nutrient supplementation through statistical experimental designs," Renewable Energy, Elsevier, vol. 113(C), pages 580-586.

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