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Progress in Chemistry 2007, Vol. 19 Issue (01): 74-79 Previous Articles   Next Articles

• Review •

The Research for Microbial Fuel Cells*

Guan Yi** ;Zhang Xin   

  1. School of Chemical Engineering and Technology, Tianjin University, Tianjin 300072, China
  • Received: Revised: Online: Published:
  • Contact: Guan Yi
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According to the progress of microbial fuel cells made in recent years, an overall review for the electron transfer mechanisms in the anode chamber of MFCs is made, and the mediator-less electron transfer processes and electron transfer processes using mediators are discussed respectively.The main factors performances, such as kinetics limitation, ohmic limitation.and transfer limitation are analysed adequately, and the possible solutions to those problems are summarized. The scientific and technical barriers of MFCs' industialization and its application prospects are discussed.

Key words: microbial fuel cell(MFCs), electron transfer, mediator, power

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[ 1 ] KimJ R , Min B , Logan B E. Appl . Microbiol . Biotechnol . ,2005 , 68 : 23 —30
[ 2 ] Feng Z , Schrêder U. Electrochemistry Communications , 2005 , 7 :1405 —1410
[ 3 ] He Z , Minteer S D , Angenent L T. Environ. Sci . Technol . ,2005 , 39(14) : 5262 —5267
[ 4 ] Liu H , Ramnarayanan R , Logan B E. Environ. Sci . Technol . ,2004 , 38(7) : 2281 —2285
[ 5 ] Angenent L T , Karim K, Al-Dahhan M H , et al . Trends Biotechnol . , 2004 , 22(9) : 477 —485
[ 6 ] Menicucci J , Beyenal H , Marsili E , et al . Environ. Sci .Technol . , 2006 , 40(3) , 1062 —1068
[ 7 ] Beliaev A S , Saffarini D A , McLaughlin J L , et al . Mol .Microbiol . , 2001 , 39(3) : 722 —730
[ 8 ] Nevin K P , Lovley D R. Appl . Environ. Microbiol . , 2002 , 68(5) : 2294 —2299
[ 9 ] Park D H , Zeikus J G. Appl . Microbiol . Biotechnol . , 2002 , 59(1) : 58 —61
[10] Vandevivere P , Verstraete W. Basic Biotechnology (eds. Ratledge C , Kristiansen B) . Cambridge University Press , 2001. 531 —557
[11] Kostka J E , Dalton D D , Skelton H , et al . Appl . Environ.Microbiol . , 2002 , 68(12) : 6256 —6262
[12] Roller S D. J . Chem. Technol . Biotechnol . B : Biotechnol . ,1984 , 34(1) : 3 —12
[13] Pham C A , Jung S L , Phung N T , et al . FEMS Microbiology Letters , 2003 , 223 : 129 —134
[14] Bond D R , Holmes D E , Tender L M, et al . Science , 2002 , 295(5554) : 483 —485
[15] Bond D R , Loveley D R. Appl . Environ. Microbiol . , 2003 , 69(3) : 1548 —1555
[16] Chaudhuri S K, Loveley D R. Nature Biotechnology , 2003 , 21(10) : 1229 —1232
[17] Park H S , KimB H , Kim H S , et al . Anaerobe , 2001 , 7 : 297 —306
[18] McKinlay J B , Zeikus J G. Appl . Environ. Microbiol . , 2004 , 70(6) : 3467 —3474
[19] Rosso K M, Zachara J M, Fredrickson J K, et al . Geochim.Cosmochim. Acta , 2003 , 67(5) : 1081 —1087
[20] Choi Y, Kim N , Kim S , et al . Bull . Koran Chem. Soc. , 2003 ,24(4) : 437 —440
[21] Newman D K, Kolter R. Nature , 2000 , 405 : 94 —97
[22] Rabaey K, Boon N , Siciliano S D , et al . Appl . Environ.Microbiol . , 2004 , 70(9) : 5373 —5382
[23] Kim H J , Hyun M S , Chang I S , et al . J . Microbiol .Biotechnol . , 1999 , 9 : 365 —367
[24] Rabaey K, Boon N , Hofte M, et al . Environ. Sci . Technol . ,2005 , 39(9) : 3401 —3408
[25] Hernandez M E , Kappler A , Newman D K. Appl . Environ.Microbiol . , 2004 , 70(2) : 921 —928
[26] Habermann W, Pommer E H. Appl . Microbiol . Biotechnol . ,1991 , 35(1) : 128 —133
[27] Schrêder U , Niessen J , Scholz F. Angew. Chem. Int . Ed.Engl . , 2003 , 42(25) : 2880 —2883
[28] Appleby A J , Foulkes F R. Fuel Cell Handbook. New York : Van Nostrand Reinhold , 1989
[29] Larminie J , Dicks A. Fuel Cell Systems Explained. Chichester :John Wiley &Sons , Ltd. , 2000
[30] Rabaey K, Lissens G, Siciliano S D , et al . BiotechnologyLetters ,2003 , 25 : 1531 —1535
[31] Rabaey K. Wat . Sci . Technol . , 2005 , 52(1P2) : 515 —523
[32] Oh S E , Logan B E. Appl . Microbiol . Biotechnol . , 2005 , 70(2) : 162 —169
[33] Moon H , Chang I S , Kim B H. Bioresource Technology , 2006 ,97(4) : 621 —627
[34] Bergel A , Feron D , Mollica A. Electrochemistry Communications ,2005 , 7 : 900 —904
[35] Topcagic S , Minteer S D. Electrochimica Acta , 2006 , 51 (11) :2168 —2172
[36] Mench M M, Wang C Y, Thynell S T. Int . J . Trans.Phenomena , 2001 , 3(3) : 151 —176
[37] Liu H , Logan B E. Environ. Sci . Technol . , 2004 , 38 (14) :4040 —4046
[38] Min B , Logan B E. Environ. Sci . Technol . , 2004 , 38 (27) :5809 —5814
[39] Rabaey K, Clauwaert P , Aelterman P , et al . Environ. Sci .Technol . , 2005 , 39(20) : 8077 —8082
[40] Oh S E , Min B , Logan B E. Environ. Sci . Technol . , 2004 , 38(18) : 4900 —4904
[41] Brian C H S , Heinzel A. Nature , 2001 , 414 : 345 —352
[42] Reshetilov A N. Applied Biochemistry and Microbiology , 2005 ,41(5) : 442 —449
[43] Jasinski R. Nature , 1964 , 201 : 1212 —1213
[44] Fukuzumi S , Imahori H. Electron Transfer in Chemistry , 2001 ,2 : 927 —975
[45] Baranton S , Coutanceau C , Roux C , et al . J . Electroanal .Chem. , 2005 , 577 : 223 —234
[46] Vega C A , Fernandez I. Bioelectrochem. Bioenerg. , 1987 , 17(2) : 217 —222
[47] Cooney M J , Roschi E , Marison I W, et al . Enzyme Microb.Technol . , 1996 , 18(3) : 358 —365
[48] McKinlay J B , Zeikus J G. Appl . Environ. Microbiol . , 2004 , 70(6) : 3467 —3474
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Abstract

The Research for Microbial Fuel Cells*