A novel cost-effective technology to convert sucrose and homocelluloses in sweet sorghum stalks into ethanol

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• 作者：Jihong Li (1) (2)
  Shizhong Li (1) (2)
  Bing Han (1) (2)
  Menghui Yu (1) (2)
  Guangming Li (1) (2)
  Yan Jiang (1) (2)
  
• 关键词：Sweet sorghum stalks ; Alkaline pretreatment ; Solid ; state fermentation ; Bioethanol
• 刊名：Biotechnology for Biofuels
• 出版年：2013
• 出版时间：December 2013
• 年：2013
• 卷：6
• 期：1
• 全文大小：563 KB
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• 作者单位：Jihong Li (1) (2)
  Shizhong Li (1) (2)
  Bing Han (1) (2)
  Menghui Yu (1) (2)
  Guangming Li (1) (2)
  Yan Jiang (1) (2)
  
  1. Institute of Nuclear and New Energy Technology, Tsinghua University, Beijing, 100084, People’s Republic of China
  2. Beijing Engineering Research Center of Biofuels, MOST-USDA joint research center for biofuels, Beijing, 100084, People’s Republic of China
  
• ISSN：1754-6834

文摘

Background Sweet sorghum is regarded as a very promising energy crop for ethanol production because it not only supplies grain and sugar, but also offers lignocellulosic resource. Cost-competitive ethanol production requires bioconversion of all carbohydrates in stalks including of both sucrose and lignocellulose hydrolyzed into fermentable sugars. However, it is still a main challenge to reduce ethanol production cost and improve feasibility of industrial application. An integration of the different operations within the whole process is a potential solution. Results An integrated process combined advanced solid-state fermentation technology (ASSF) and alkaline pretreatment was presented in this work. Soluble sugars in sweet sorghum stalks were firstly converted into ethanol by ASSF using crushed stalks directly. Then, the operation combining ethanol distillation and alkaline pretreatment was performed in one distillation-reactor simultaneously. The corresponding investigation indicated that the addition of alkali did not affect the ethanol recovery. The effect of three alkalis, NaOH, KOH and Ca(OH)2 on pretreatment were investigated. The results indicated the delignification of lignocellulose by NaOH and KOH was more significant than that by Ca(OH)2, and the highest removal of xylan was caused by NaOH. Moreover, an optimized alkali loading of 10% (w/w DM) NaOH was determined. Under this favorable pretreatment condition, enzymatic hydrolysis of sweet sorghum bagasse following pretreatment was investigated. 92.0% of glucan and 53.3% of xylan conversion were obtained at enzyme loading of 10 FPU/g glucan. The fermentation of hydrolyzed slurry was performed using an engineered stain, Zymomonas mobilis TSH-01. A mass balance of the overall process was calculated, and 91.9?kg was achieved from one tonne of fresh sweet sorghum stalk. Conclusions A low energy-consumption integrated technology for ethanol production from sweet sorghum stalks was presented in this work. Energy consumption for raw materials preparation and pretreatment were reduced or avoided in our process. Based on this technology, the recalcitrance of lignocellulose was destructed via a cost-efficient process and all sugars in sweet sorghum stalks lignocellulose were hydrolysed into fermentable sugars. Bioconversion of fermentable sugars released from sweet sorghum bagasse into different products except ethanol, such as butanol, biogas, and chemicals was feasible to operate under low energy-consumption conditions.