中文
Earlier issues
Announcement
More
Progress in Chemistry 2007, Vol. 19 Issue (0708): 1129-1133 Previous Articles   Next Articles

• Special issues •

Fuel Ethanol Production from Lignocellulosic Biomass

Zhang Suping;Yan Yongjie**;Ren Zhengwei;Li Tingchen   

  1. Centre for Biomass Energy Technology,East China University of Science and Technology,Shanghai 200237,China
  • Received: Revised: Online: Published:
PDF ( 2956 ) Cited
Export

EndNote

Ris

BibTeX

Lignocellulosic biomass is considered one of the most promising feedstock for producing fuel ethanol due to its global availability and environmental benefits. The conversion process of fuel ethanol utilizing lignocellulosic biomass involves hydrolysis and fermentation. In this paper, the mechanisms of conversion of lignocellulosic biomass to ethanol are introduced. The technological progresses of fuel ethanol production from lignocellulosic biomass is extensively reviewed and the key problems to be solved of different processes are also discussed. Meanwhile, the technological economics analyses of the process are provided. Finally,the status of practical application and the prospect of industrial application of fuel ethanol producing from lignocellulosic biomass are presented.
Key words: lignocellulosic biomass, fuel ethanol, hydrolysis, fermentation

CLC Number: 

[ 1 ] Wheals A E , Basso L C , Alves D M G, et al . Trends in Biotechnology. 1999 , 17 : 482 —487
[ 2 ] Spath P L , Dayton D C. National Renewable Energy Laboratory ,2003 , 12 : 64 —66
[ 3 ] Yuan Z H. International Journal of Energy Technology and Policy ,2002 , (1) : 1 —15
[ 4 ] 吴创之(Wu C Z) , 马隆龙(Ma L L) . 生物质能现代化利用技术(Application Technology of Biomass in Modern Time) . 北京: 化学工业出版社(Beijing : Chemical Industry Press) ,2003. 173 —196
[ 5 ] 岳萱(Yue X) , 乔卫红(Qiao W H) , 申凯华(Shen K H) . 精细化工(Fine Chemicals) , 2001 , 18(11) : 670 —673
[ 6 ] Funaoka M, Matsubara M, Seki N. Biotechnology and Bioengineering , 2004 , 46(6) : 545 —552
[ 7 ] Hahn-Hagerdal B , Galbe M, Gorwa-Grauslund M F , et al . Trends in Biotechnology , 2006 , 24 : 549 —556
[ 8 ] Hamelinck C N , van Hooijdonk G, Faaij A P C. Biomass and Bioenergy , 2005 , 28 : 384 —410
[ 9 ] James F. [2007-03-29 ] . http ://energy.seekingalpha.com/article/13493
[10] Wooley R , Ma Z , Wang N H L. IEC Res. , 1998 , 37 ( 9) :3679 —3709
[11] 李浔(Li X) . 华东理工大学博士学位论文(Doctorial Thesis of East China University of Science and Technology) , 2004. 67 —89
[12] Choi C H , Mathews A P. Bioresource Technology , 1996 , 58 :101 —106
[13] Xiang Q , Lee Y Y, Torget R W. Applied Biochemistry and Biotechnology , 2004 , 113/116 : 1127 —1138
[14] Lee Y Y, Iyer P , Toget R W. Advanced Biochemistry and Biotechnology , 1999 , 65 : 93 —115
[15] Converse A O. Bioresource Technology , 2002 , 81 : 109 —116
[16] [2007-03-28 ] . http://zfacts.com/p/85.html
[17] Holtzapple M T. Jun J H , Ashok G, et al . Applied Biochemistry and Biotechnology , 1991 , 28/29 : 59 —74
[18] Esteghlalian A , Hashimoto A G, Fenske J J , et al . Bioresource Technology , 1997 , 59 : 129 —136
[19] Sivers M V , Zacchi G. Bioresource Technol . , 1995 , 51 : 43 —52
[20] Wyman C E , Dale B E , Elander R T , et al . Bioresource Technology , 2005 , 96 : 2026 —2032
[21] Ghose T K, Tyagi R D. Biotechnology and Bioengineering , 1979 ,21(8) : 1387 —1400
[22] Ghose T K, Roychoudhury P K, Ghosh P. Biotechnology and Bioengineering , 1984 , 26 : 377 —381
[23] South C R , Hogsett D A L , Lynd L R. Enzyme and Microbial Technology , 1999 , 17 : 797 —803
[24] Philippidis G P , Smith T K. Applied Biochemistry and Biotechnology , 1995 , 51/52 : 117 —124
[25] Ballesteros I , Oliva J M, Carrasco J , et al . Applied Biochemistry and Biotechnology , 1998 , 70/72 : 369 —381
[26] McMillan J D , Newman M M, Templeton D W, et al . Applied Biochemistry and Biotechnology , 1999 , 77/79 : 649 —665
[27] Krishna S H , Prasanthi K, Chowdary G V , et al . Process Biochemistry , 1998 , 33(8) : 825 —830
[28] Eklund R , Sacchic N. Enzyme and Microbial Technology , 1995 ,17 : 255 —259
[29] 柴梅(Chai M) . 华东理工大学硕士学位论文(Master Thesis of East China University of Science and Technology) , 2007. 6 —8
[30] 袁振宏(Yuan Z H) . 华东理工大学博士学位论文(Doctorial Thesis of East China University of Science and Technology) ,2006. 16 —21
[31] Zhuang J . Master Thesis of University of Kentucky , 2004
[32] Papinutti V L , Forchia F. Journal of Food Engineering , 2007 ,81 : 54 —59
[33] Larsson S , Quintana-Sainz A , Reimann A , et al . App. Biochem.Biotechnol . , 2000 , 84P86 : 617 —632
[34] Agbogbo F K, Coward-Kelly G, Torry2Smith M, et al . Process Biochemistry , 2006 , 41 : 2333 —2336
[35] Zhang M, Eddy C , Deanda K. Science , 1995 , 267 : 240 —243
[36] IngramL O , Aldrich H C , Borges A C C , et al . Biotechnol .Prog. , 1999 , 15 : 855 —866
[37] Lynd L R , van Zyl W H , McBride J E , et al . Curr. Opin.Biotechnol . , 2005 , 16 : 577 —583
[38] Sheehan J , Himmel M. Biotechnol . Prog. , 1999 , 15 : 817 —827
[39] Kaylen M, van Dyne D L , Choi Y S , et al . Bioresource Technol . , 2000 , 72 : 19 —32
[40] Aden A , Ruth M, Ibsen K, et al . National Renewable Energy Laboratory (NREL) Report . TP-510-32438 , 2002
[41] McCoy M. Chem. Eng. News , 1998 , 76 : 29 —32
[42] Sharon B. [ 2007-03-28 ] . http://www.grist.org/news/maindish/2006/12/12/boddy
[1] Zitong Zhao, Zhenzhen Zhang, Zhihong Liang. The Activity Origin, Catalytic Mechanism and Future Application of Peptide-Based Artificial Hydrolase [J]. Progress in Chemistry, 2022, 34(11): 2386-2404.
[2] Qilu Yao, Hongxia Du, Zhang-Hui Lu. Catalytic Hydrolysis of Ammonia Borane for Hydrogen Production [J]. Progress in Chemistry, 2020, 32(12): 1930-1951.
[3] Ying Qiao, Na Teng, Chengkai Zhai, Haining Na, Jin Zhu. High Efficient Hydrolysis of Cellulose into Sugar by Chemical Catalytic Method [J]. Progress in Chemistry, 2018, 30(9): 1415-1423.
[4] Zhou Yan, Zhao Xuebing, Liu Dehua. Effects of Non-Ionic Surfactant on the Enzymatic Hydrolysis of Lignocellulose and Corresponding Mechanism [J]. Progress in Chemistry, 2015, 27(11): 1555-1565.
[5] Guo Xiao, Yan Yani, Zhang Yahong, Tang Yi. Heterogeneously Catalytic Transformation of Biomass-Derived Sugars [J]. Progress in Chemistry, 2013, 25(11): 1915-1927.
[6] Fu Jing, Wang Meng, Liu Weixi, Chen Tao. Latest Advances of Microbial Production of 2,3-Butanediol [J]. Progress in Chemistry, 2012, 24(11): 2268-2276.
[7] Zhang Jianming, Zhai Shangru, Huang Dezhi, Zhai Bin, An Qingda. Solid Heteropolyacids (HPAs) in Hydrolytic Conversion of Biomass [J]. Progress in Chemistry, 2012, 24(0203): 433-444.
[8] Ji Xiaojun, Nie Zhikui, Li Zhiyong, Gao Zhen, Huang He. Biotechnological Production of 2,3-Butanediol [J]. Progress in Chemistry, 2010, 22(12): 2450-2461.
[9] . Dilute Acid Hydrolysis Reaction of Biomass Hemicellulose [J]. Progress in Chemistry, 2010, 22(04): 654-662.
[10] Zhang Mingjia Su Rongxin Qi Wei He Zhimin. Enzymatic Conversion of Lignocellulose into Sugars [J]. Progress in Chemistry, 2009, 21(05): 1070-1074.
[11] Hu Zhanbo1,2* Chai Xinsheng3 Wang Jingquan2 Kong Hainan1. A New Approach of Bio-Refinery Based on Pulp and Paper Platform [J]. Progress in Chemistry, 2008, 20(09): 1439-1446.
[12] Xu Dongyan1**,Zhang Huamin2,Ye Wei2 . Hydrogen Production from Sodium Borohydride [J]. Progress in Chemistry, 2007, 19(10): 1598-1605.
[13] Scientific Research Platform of the Ministry of Education,State Key Laboratory of Pulp and Paper Engineer,South China University of Technology,Guangzhou 510640,China. High-Value Chemicals from Lignocellulosic Biomass [J]. Progress in Chemistry, 2007, 19(0708): 1206-1216.
[14] He Beihai,Lin Lu**,Sun Runcang,Sun Yong. Chemical Hydrolysis of Lignocellulosics into Fermentable Sugars [J]. Progress in Chemistry, 2007, 19(0708): 1141-1146.
[15] Liu Li,Sun Junshe**,Kang Liping,Liu Ping. The Fuel Ethanol Production from Sweet Sorghum Stalk [J]. Progress in Chemistry, 2007, 19(0708): 1109-1115.