臺灣博碩士論文加值系統

隨著世界能源問題日益嚴重，不同型態的再生能源不斷被開發。微生物燃料電池係利用微生物分解有機物產生電力，是一種新興再生能源的技術。在多種微生物燃料電池類型中，有機廢棄物微生物燃料電池的實用性較高。本研究目的為於實驗室建置有機廢棄物微生物燃料電池，並探討影響有機廢棄物微生物燃料電池電力之因素。
本研究擬探討有機廢棄物微生物燃料電池產電最佳化條件，以有機廢棄物微生物燃料電池產電作為再生能源之可行性。微生物燃料電池以1.5 L與4.5 L矩形壓克力槽體兩種尺寸(含單槽與雙槽)進行，植種污泥取自台中市福田水資源回收中心之污泥厭氧消化槽，並以合成有機廢棄物作為微生物利用碳源基質進行實驗。極板陰極與陽極分別以碳氈、碳板、碳紙、不鏽鋼板與碳氈等加以搭配組合，進行有機廢棄物微生物燃料電池極板產電最佳化之研究。
研究結果顯示，單槽微生物燃料電池，最佳產電效果以陽極為碳氈，陰極為碳板之極板組合，1.5 L槽體產電最高可達1.295 V，功率密度為4.08 mW/m2；4 L槽體產電最高可達0.625 V，功率密度1.87 mW/m2；雙槽微生物燃料電池，最佳產電效果以陽極為碳氈，陰極為碳氈之極板組合，1.5 L槽體產電最高可達0.83 V，功率密度為25.21 mW/m2；4 L槽體產電最高0.732 V，功率密度44.28 mW/m2。
有機廢棄物微生物燃料電池添加灰燼實驗中，添加0.2 g/g-VS底灰，沒有顯著提升產電性能，可能是微生物需長時間來適應灰燼釋出之金屬，以利其厭氧生物代謝程式之增進，1.5 L槽體產電最高可達0.692 V，功率密度為2.02 mW/m2；4 L槽體產電最高可達0.63 V，功率密度2.275 mW/m2；雙槽微生物燃料電池，最佳產電效果以陽極為碳氈，陰極為碳氈之極板組合，1.5 L槽體產電最高可達0.767 V，功率密度為17.51 mW/m2；4 L槽體產電最高0.73 V，功率密度15.89 mW/m2。

This study aimed to investigate the optimization operation conditions of microbial fuel cell (MFC) with organic waste and the bio-electricity potential from organic waste by microorganisms. MFC contained two sizes of 1.5 L and 4.5 L acrylic rectangular tanks with one or two apartment. Anaerobic sludge seeding was obtained from Fu-Tien wastewater treatment plant in central Taiwan and organic substrate was prepared by office paper, newspaper, yard waste and food waste. Cathode was set up with carbon felt, carbon plate, carbon paper, steel plate while anode was set up with only carbon felt for various plates combination to conduct the experiment.
Results showed that MFC (single-apartment) could reach voltage and power density of 1.295 V and 4.08 mW/m2 for 1.5 L MFC and those of 0.625 V and 1.87 mW/m2 for 4 L MFC. For MFC with two apartments, voltage and power density could reach 0.83 V and 25.21 mW/m2 for 1.5 L MFC while those could reach 0.732 V and 44.28 mW/m2 for 4 L MFC.
For MFC with MSWI bottom ash addition (0.2 g/g-VS), voltage did not increase as expected. For single-apartment MFC, voltage and power density of 0.692 V and 2.02 mW/m2 for 1.5 L MFC and those of 0.63 V and 2.275 mW/m2 for 4 L MFC was found. For two-apartment MFC, voltage and power density of 0.767 V and 17.51 mW/m2 for 1.5 L MFC and those of 0.73 V and 15.89 mW/m2 for 4 L MFC could be reached. It was thought that suitable bottom ash addition might need longer term for microorganisms to adapt the potential release of metals for potential increase of voltage and power density.

總目錄
中文摘要 I
ABSTRACT III
誌謝 IV
總目錄 V
表目錄 IX
圖目錄 X
第一章 前言 1
1.1研究動機 1
1.2研究目的 2
1.3研究內容 3
第二章 文獻回顧 4
2.1 微生物燃料電池發展 4
2.2 微生物燃料電池之介紹 5
2.2.1 陽極反應槽 7
2.2.2 陰極反應槽 8
2.2.3產電與產甲烷 9
2.3微生物燃料電池種類 10
2.3.1 雙槽式微生物燃料電池 11
2.3.2 單槽式微生物燃料電池 14
2.4 影響微生物燃料電池效能之操作參數 19
2.4.1 基質 20
2.4.1.1化工廢水 20
2.4.1.2 藥物廢水 21
2.4.1.3 畜牧養殖廢水 22
2.4.1.4 食品加工廢水 22
2.4.1.5 垃圾滲出液 23
2.4.1.6含氮廢水 24
2.4.2 電極材料 26
2.4.3 催化條件 26
2.4.4 電子接受者 28
第三章 研究材料與方法 29
3.1 研究架構與流程 29
3.2 有機廢棄物微生物燃料電池之架設 30
3.2.1 雙槽式微生物燃料電池 30
3.2.2 單槽式微生物燃料電池 32
3.2.3 質子交換膜 34
3.2.4 電極材料 34
3.2.5 厭氧污泥 38
3.2.6 有機垃圾基質 39
3.3 催化條件實驗 40
3.3.1 電場實驗架設 40
3.3.2 磁場實驗架設 41
3.3.3 灰燼實驗架設 41
3.3.4 超音波水解基質 42
3.3.5 鹼水解基質 43
3.3.6 鐵氰化鉀實驗操作 43
3.4 實驗使用之儀器設備 43
3.5 基本參數分析 46
3.5.1 總固體物(TS)及揮發性固體物(VS)測定方法 46
3.5.2化學需氧量(COD)分析 47
3.5.3鹼度與揮發酸(VAS) 48
3.6 電能計算及分析 49
3.6.1 電流及功率密度 49
3.4.2 庫侖效率 (Coulombic efficiency) 50
第四章 結果與討論 51
4.1 小型單槽微生物燃料電池不同極板之產電情形 52
4.2小型雙槽微生物燃料電池不同極板之產電情形 54
4.3大型單槽微生物燃料電池不同極板之產電情形 56
4.4大型雙槽微生物燃料電池不同極板之產電情形 59
4.5小型單槽微生物燃料電池添加灰燼之產電情形 61
4.6小型雙槽微生物燃料電池添加灰燼之產電情形 64
4.7大型單槽微生物燃料電池添加灰燼之產電情形 66
4.8大型雙槽微生物燃料電池添加灰燼之產電情形 69
第五章 結論與建議 71
5.1 結論 71
5.2 建議 72
文獻參考 73



表目錄
表2.1 陽極反應化學式 8
表2.2 陰極標準電池半反應 9
表2.2單槽與雙槽MFC 的內電阻 18
表2.3單槽與雙槽MFC 的功率密度和庫侖效率 19
表2.4其他燃料電池文獻比較 25
表3.1 質子交換膜基本資料 34
表3.2 本研究使用之極板基本資料 35
表3.3本研究使用之碳氈極板基本性質 36
表3.4本研究使用之碳氈極板EDS元素含量表 36
表3.5本研究使用之碳紙極板EDS元素含量表 37
表3.6本研究使用之碳紙極板基本性質 38
表3.7合成垃圾、台中市垃圾與全台灣垃圾元素分析 40
表3.8 本研究使用灰燼之重金屬含量 42
表3.9 本研究所使用之儀器設備 44


圖目錄

圖2.1 雙槽MFC結構示意圖 7
圖2.2常見的雙槽式燃料電池類型(A)典型兩槽式H型微生物燃料電池；(B)矩形微生物燃料電池；(C)微型微生物燃料電池；(D)上流式微生物燃料電池；(E)U形微生物燃料電池 12
圖2.4常見的單槽式燃料電池類型(A)典型單槽式微生物燃料電池；(B)圓柱式單槽微生物燃料電池；(C)管柱式單槽微生物燃料電池 15
圖2.5空氣陰極單槽式微生物燃料電池示意圖(A)組裝體；(B)除頂部塞子外的拆裝部分 16
圖3.1 本研究實驗架構圖 30
圖3.2 雙槽微生物燃料電池示意圖 31
圖3.3 雙槽微生物燃料電池實體圖 32
圖3.4 單槽微生物燃料電池示意圖 33
圖3.5 單槽微生物燃料電池實體圖 33
圖3.6本研究使用之碳氈極板EDS圖 37
圖3.7本研究使用之碳紙極板SEM圖 38
圖4.1 小型單槽微生物燃料電池不同極板之產電變化(圖示左為陽極、右為陰極) 52
圖4.2 小型單槽微生物燃料電池不同極板之極化曲線(圖示左為陽極、右為陰極) 53
圖4.3 小型雙槽微生物燃料電池不同極板之產電變化(圖示左為陽極、右為陰極) 54
圖4.4 小型雙槽微生物燃料電池不同極板之極化曲線(圖示左為陽極、右為陰極) 55
圖4.5 大型單槽微生物燃料電池不同極板之產電變化(圖示左為陽極、右為陰極) 57
圖4.6 大型單槽微生物燃料電池不同極板之極化曲線(圖示左為陽極、右為陰極) 58
圖4.7 小型雙槽微生物燃料電池不同極板之產電變化(圖示左為陽極、右為陰極) 60
圖4.8 小型雙槽微生物燃料電池不同極板之極化曲線(圖示左為陽極、右為陰極) 61
圖4.9 小型單槽微生物燃料電池添加底灰之產電變化(圖示左為陽極、右為陰極) 62
圖4.10 小型單槽微生物燃料電池添加底灰之極化曲線(圖示左為陽極、右為陰極) 63
圖4.11 小型雙槽微生物燃料電池添加底灰之產電變化(圖示左為陽極、右為陰極) 65
圖4.12 小型雙槽微生物燃料電池添加底灰之極化曲線(圖示左為陽極、右為陰極) 66
圖4.13 大型單槽微生物燃料電池添加底灰與飛灰之產電變化(圖示左為陽極、右為陰極) 67
圖4.14 大型單槽微生物燃料電池添加底灰與飛灰之極化曲線(圖示左為陽極、右為陰極) 68
圖4.15 大型雙槽微生物燃料電池添加灰燼之產電變化(圖示左為陽極、右為陰極) 69
圖4.16 大型雙槽微生物燃料電池添加底灰與飛灰之極化曲線(圖示左為陽極、右為陰極) 70

Allen, R. M., and Bennetto, H. P., “Microbial fuel cells: electricity production from carbohydrates,” Applied Biochemistry and Biotechnology, Vol. 39, No. 40, pp.27-40(1993).
Chaudhuri, S. K., and Lovley, D. R., “Electricity generation by direct oxidation of glucose in mediatorless microbial fuel cells,” Nature Biotechnology, Vol. 21, No. 10, pp.1229-1232(2003).
Delaney, G. M., Bennetto, H. P., Mason, J. R., Roller, S. D., Stirling, J. L., and Thurston, C. F., “Electron-transfer coupling in microbial fuel cells. 2. Performance
Du, Z., Li, H., and Gu, T., “A state of the art review on microbial fuel cells: A promising technology for wastewater treatment and bioenergy,” Biotechnology Advances, Vol. 25, No. 5, pp.464-482(2007).
Galvez, A., Greenman, J., and Ieropoulos, I., “Landfill leachate treatment with microbial fuel cells; scale-up through plurality,” Bioresource Technology, Vol. 100, No. 21, pp.5085-5091(2009).
Gil, G. C., Chang, I. S., Kim, B. H., Kim, M., Jang, J. K., Park, H. S., and Kim, H. J., “Operational parameters affecting the performannce of a mediator-less microbial fuel cell,” Biosensors and Bioelectronics, Vol. 18, No. 4, pp.327-334(2003).
He, Z., Minteer, S. D., and Angenent, L. T., “Electricity generation from artificial wastewater using an upflow microbial fuel cell,” Environmental Science & Technology, Vol. 39, No. 14, pp.5262-5267(2005).
He, Z., Wagner, N., Minteer, S. D., and Angenent, L. T., “An upflow microbial fuel cell with an interior cathode: assessment of the internal resistance by impedance spectroscopy,” Environmental Science & Technology, Vol. 40, No. 17, pp.5212-5217(2006).
Kiely, P. D., Cusick, R., Call, D. F., Selembo, P. A., Regan, J. M., and Logan, B. E., “Anode microbial communities produced by changing from microbial fuel cell to microbial electrolysis cell operation using two different wastewaters,” Bioresource Technology, Vol. 102, No. 1, pp.388-394(2011).
Kim, B. H., Kim, H. J., Hyun, M. S., and Park, D. H., “Direct electrode reaction of Fe(III)-reducing bacterium, Shewanella putrefaciens,” Journal of Microbiology and Biotechnology, Vol. 9, No. 2, pp.127-131(1999).
Kim, B. H., Park, D. H., Shin, P. K., Chang, I. S., and Kim, H. J., “Mediator-less biofuel cell,” United States Patent, 1999.
Kim, J. R., Jung, S. H., Regan, J. M., and Logan, B. E., “Electricity generation and microbial community analysis of alcohol powered microbial fuel cells,” Bioresource Technology, Vol. 98, No. 13, pp.2568-2577(2007).
Kim, J. R., Min, B., and Logan, B. E., “Evaluation of procedures to acclimate a microbial fuel cell for elecricity production,” Applied Microbiology & Biotechnology, Vol. 68, No. 1, pp.23-30(2005).
Kong, X., Sun, Y., Yuan, Z., Li, D., Li, L., and La, Y., “Effect of cathode electron-receiver on the performance of microbial fuel cells,” International Journal of Hydrogen Energy, Vol. 35, No. 13, pp.7224-7227(2010).
Li, H., and Ni, J., “Treatment of wastewater from Dioscorea zingiberensis tubers used for producing steroid hormones in a microbial fuel cell,” Bioresource Technology, Vol. 102, No. 3, pp.2731-2735(2011).
Li, Z., Zhang, X., and Lei, L., “Electricity production during the treatment of real electroplating wastewater containing Cr6+ using microbial fuel cell,” Process Biochemistry, Vol. 43, No. 12, pp.1352-1358(2008).
Liu, H., and Logan, B. E., “Electricity generation using an air–cathode single chamber microbial fuel cell in the presence and absence of a proton exchange membrane,” Environmental Science & Technology, Vol. 38, No. 14, pp.4040-4046(2004).
Liu, H., Cheng, S., and Logan, B. E., “Power generation in fed-batch microbial fuel cells as a function of ionic strength, temperature, and reactor configuration,” Environmental Science & Technology, Vol. 39, No. 14, pp.5488-5493(2005).
Liu, H., Ramnarayanan, R., and Logan, B. E., “Production of electricity during wastewater treatment using a single chamber microbial fuel cell,” Environmental Science & Technology, Vol. 38, No. 7, pp.2281-2285(2004).
Lo, H. M., Liu, M. H., Pai, T. Y., Liu, W. F., Lin, C. Y., Wang, S. C., Banks, C. J., Hung, C. H., Chiang, C. F., Lin, K. C., Chen, P. H., Chen, J. K., Chiu, H. Y., Su, M. H., Kurniawan, T. A., Wu, K. C., Hsieh, C. Y., and Hsu, H. S., “Biostabilization assessment of MSW co-disposed with MSWI fly ash in anaerobic bioreactors,” Journal of Hazardous Materials, Vol. 162, No. 2-3, pp.1233-1242(2009).
Logan, B. E., “Biologically extracting energy from wastewater: biohydrogen production and microbial fuel cells,” Environmental Science & Technology, Vol. 38, No. 9, pp.160A-167A(2004).
Logan, B. E., Aelterman, P., Hamelers, B., Rozendal, R., Schröeder, U., Keller, J., Freguiac, S., Verstraete, W., and Rabaey, K., “Microbial fuel cells-challenges and applications,” Environmental science and technology, Vol. 40, No. 17, pp.5172-5180(2006).
Logan, B. E., Microbial fuel cells, John Wiley & Sons Inc, United States(2008).
Logana, B. E., Muranob, C., Scottb, K., Grayc, N. D., and Headc, I. M., “Electricity generation from cysteine in a microbial fuel cell,” Water Research, Vol. 39, No. 5, pp.942-952(2005).
Lovley, D. R., “Bug juice: harvesting electricity with microorganisms,” Nature Reviews Microbiology, Vol. 4, No. 7, pp.497-508(2006).
Lovley, D. R., “Microbial fuel cells: novel microbial physiologies and engineering approaches,” Current Opinion in Biotechnology, Vol. 17, No. 3, pp.327-332(2006).
Lovley, D. R., “The microbe electric: conversion of organic matter to electricity,” Curr Opin Biotechnol, Vol. 19, No. 6, pp.564-571(2008).
Min, B., Chang, S., and Logan, B. E., “Electricity generation using membrane and salt bridge microbial fuel cells,” Water Research, Vol. 39, No. 9, pp.1675-1686(2005).
Min, B., Kim, J., Oh, S., Regan, J. M., and Logan, B. E., “Electricity generation from swine wastewater using microbial fuel cells,” Water Research, Vol. 39, No. 20, pp.4961-4968(2005).
Mohan, S. V., Mohanakrishna, G., Reddy B. P., Saravanan, R., and Sarma, P. N., “Bioelectricity generation from chemical wastewater treatment in mediatorless (anode) microbial fuel cell (MFC) using selectively enriched hydrogen producing mixed culture under acidophilic microenvironment,” Biochemical Engineering Journal, Vol. 39, No. 1, pp.121-130(2008).
Mohan, S. V., Mohanakrishna, G., Velvizhi, G., Babu, V. L., and Sarma, P. N., “Bio-catalyzed electrochemical treatment of real field dairy wastewater with simultaneous power generation,” Biochemical Engineering Journal, Vol. 51, No. 1-2, pp.32-39(2010).
Moon, H., Chang, I. S., Jang, J. K., and Kim, B. H., “Residence time distribution in microbial fuel cell and its influence on COD removal with electricity generation,” Biochemical Engineering Journal, Vol. 27, No. 1, pp.59-65(2005).
of fuel cells containing selected microorganism-mediator-substrate combinations,” Journal of Chemical Technology and Biotechnology, Vol. 34, No. 1, pp.13-27(1984).
Oh, S. E., and Logan, B. E., “Proton exchange membrane and electrode surface areas as factors that affect power generation in microbial fuel cells,” Applied Microbiology and Biotechnology, Vol. 70, No. 2, pp.162-169(2006).
Oh, S., Min, B., and Logan, B. E., “Cathode performance as a factor in electricity generation in microbial fuel cells,” Environmental Science & Technology, Vol. 38, No. 18, pp.4900-4904(2004).
Park, D. H., and Zeikus, J. G., “Impact of electrode composition on electricity generation in a single-compartment fuel cell using Shewanella putrefaciens,” Applied Microbiology & Biotechnology, Vol. 59, No. 1, pp.58-61(2002).
Patil, S. A., Surakasi, V. P., Koul, S., Ijmulwar, S., Vivek, A., Shouche, Y. S., and Kapadnis, B. P., “Electricity generation using chocolate industry wastewater and its treatment in activated sludge based microbial fuel cell and analysis of developed microbial community in the anode chamber,” Bioresource Technology, Vol. 100, No. 21, pp.5132-5139(2009).
Piccolino, M., “Animal electricity and the birth of electrophysiology: the legacy of Luigi Galvani.,” Brain Research Bulletin, Vol. 46, No. 5, pp.381-407(1988).
Potter, M. C., “Electrical effects accompanying the decomposition of organic compounds,” Proceedings of the Royal Society of London, Vol. 84, No. 571, pp.260-276(1911).
Rabaey, K., and Verstraete, W., “Microbial fuel cells: novel biotechnology for energy generation,” Trends in Biotechnology, Vol. 23, No. 6, pp.291-298(2005).
Rabaey, K., Boon, N., Siciliano, S. D., Verhaege, M., and Verstraete, W., “Biofuel cells select for microbial consortia that self-mediate electron transfer,” Applied and environmental microbiology, Vol. 70, No. 9, pp.5373-5382(2004).
Rabaey, K., Clauwaert, P., Aelterman, P., and Verstraete, W., “Tubular microbial fuel cells for efficient electricity generation,” Environmental Science & Technology, Vol. 39, No. 20, pp.8077-8082(2005).
Rabaey, K., Lissens, G., Siciliano, S. D., and Verstraete, W., “A microbial fuel cell capable of converting glucose to electricity at high rate and efficiency,” Vol. 25, No. 18, pp.1531-1535(2003).
Rabaey, K., Ossieur, W., Verhaege, M., and Verstraete, W., “Continuous microbial fuel cells convert carbohydrates to electricity,” Water Science and Technology, Vol. 52, No. 1-2, pp.515-523(2005).
Rabaey, K., Rodriguez, J., Blackall, L., Keller, J., Gross, P., Batstone, D., Verstraete, W., and Nealson, K., “Microbial ecology meets electrochemistry: Electricity-driven and driving communities,” The ISME Journal, Vol. 1, No. 1, pp.9-18(2007).
Ringeisen, B. R., Henderson, E., Wu, P. K., Pietron, J., Ray, R., Little, B., Biffinger, J. C., and Jones-Meehan, J. M., “High power density from a miniature microbial fuel cell using Shewanella oneidensis DSP10,” Environmental Science & Technology, Vol. 40, No. 8, pp.2629-2634(2006).
Scott, K., and Murano, C., “A study of a microbial fuel cell battery using manure sludge waste,” Journal of Chemical Technology & Biotechnology, Vol. 82, No. 9, pp.809-817(2007).
Sell, D., Kreysa, G., and Kraemer, P., Potential Applications of Biochemical Fuel-Cells as Analytical Tools, 5th European Congress on Biotechnology, Proceedings, Denmark, pp.539-543(1990).
Shukla, A. K., Suresh, P., Berchmans, S., and Rajendran, A., “Biological fuel cells and their applications,” Current Science, Vol. 87, No. 4, pp.455-468(2004).
Virdis, B., Rabaey, K., Yuan, Z., and Keller, J., “Microbial fuel cells for simultaneous carbon and nitrogen removal,” Water Research, Vol. 42, No. 12, pp.3013-3024(2008).
Wei, L., Han, H., and Shen, J., “Effects of cathodic electron acceptors and potassiumferricyanide concentrations on the performance of microbial fuel cell,” Vol.No.2012).
Yokoyama, H., Ohmori, H., Ishida, M., Waki, M., and Tanaka, Y., “Treatment of cowwaste slurry by a microbial fuel cell and the properties of the treated slurry as a liquid manure,” Animal Science Journal, Vol. 77, No. 6, pp.634-638(2006).
Yu, C. P., Liang, Z., Das, A., and Hu, Z., “Nitrogen removal from wastewater using membrane aerated microbial fuel cell techniques,” Water Research, Vol. 45, No. 3, pp.1157-1164(2011).
丁巍巍、汪家權、呂劍，「微生物燃料電池處理苯酚廢水」，合肥工業大學學報：自然科學版，第33卷，第1期，第94-96頁(2010)。
孔維芳、郭慶傑、王許雲，「不同介體厭氧流化床微生物燃料電池產電特性研究」，農業工程學報，第25卷，第5期，第858-863頁(2011)。
孔曉英、孫永明、李連華、李東、楊改秀，「不同底物對微生物燃料電池產電性能的影響」，高校化學工程學報，第27卷，第1期，第158-188頁(2011)。
尤世界、趙慶良、薑君秋，「廢水同步生物處理與生物燃料電池發電研究」，環境科學學報，第27卷，第9期，第1786-1790頁(2006)。
武晨、張嘉琪、王曉麗、池強龍、胡瑛，「以苯胺和葡萄糖為燃料的微生物燃料電池的產電特性研究」，環境科學學報，第31卷，第6期，第1227-1232頁(2011)。
紀占武、鄭文範，「關於發展生物能源化解能源危機的思考」，東北大學學報(社會科學版)，第11卷，第6期，第490-495頁(2009)。
祝學遠、馮雅麗、李少華，「單室直接微生物燃料電池的陰極製作及構建」，過程工程學報，第7卷，第3期，第594-597頁(2007)。
張培遠、劉中良，「矩形微生物燃料電池性能的分析」，微生物學通報，第38卷，第6期，第832-838頁(2011)。
張曉艷、滕洪輝，「以垃圾滲濾液為燃料的微生物燃料電池產電性能」，吉林大學學報(理學版)，第49卷，第6期，第1162-1166頁(2011)。
曹效鑫，「微生物燃料電池中產電菌與電極的作用機制及其應用」，博士論文，清華大學環境科學與工程系，北京(2009)。
曹效鑫、梁鵬、黃霞，「“三合一”微生物燃料電池的產電特性研究」，環境科學學報，第26卷，第8期，第1252-1257頁(2006)。
梁鵬，張玲，黃霞，「雙筒型微生物燃料電池生物陰極反硝化研究」，環境科學，第31卷，第8期，第1932-1936頁(2010)。
陳青、周順桂、袁勇、徐榮險、胡佩，「外阻對污泥微生物燃料電池產電以及有機物降解的影響」，生態環境學報，第20卷，第5期，第946-950頁(2011)。
陳暘、錢超、錢冬全、王麓、劉龍飛，「以天然混合菌接種的微生物燃料電池產電性能研究」，常熟理工學院學報(自然科學)，第25卷，第4期，第61-78頁(2011)。
黃昱翔，「有機廢棄物高溫固態厭氧醱酵產氫特性之研究」，碩士論文，國立中央大學環境工程研究所，桃園(2010)。
溫青、吳英、王貴領，「雙極室聯合處理啤酒廢水的微生物燃料電池」，高等學校化學學報，第31卷，第6期，第1231-1234頁(2010)。
溫青、孫茜、趙立新，「微生物燃料電池對廢水中對硝基苯酚的去除」，現代化工，第29卷，第4期，第40-42頁(2009)。
趙世輝、李友明、萬小芳、莫光權，「木質素磺酸鹽在微生物燃料電池中的降解及產電性能研究」，環境工程學報，第5卷，第7期，第1647-1650頁(2011)。
劉晶晶、孫永明、孔曉英、李連華、李穎、田沈、楊秀山、袁振宏，「不同接種條件下微生物燃料電池產電特性分析」，中國環境科學，第31卷，第10期，第1651-1656頁(2011)。
蔡小波、楊毅、孫彥平，「生物燃料電池利用甘藷燃料乙醇廢水產電的研究」，環境科學，第31卷，第10期，第2512-2517頁(2010)。
鄭美華、黃邦根，「全球能源危機條件下的中國經濟可持續發展研究」，北方經濟，第10卷，第19期，第38-39頁(2008)。
遲美玲，「提高微生物燃料電池性能的電極材料研究」，碩士論文，南開大學環境科學與工程學院，天津(2011)。
謝珊、梁鵬、李亮、黃霞，「兩瓶型微生物燃料電池處理垃圾滲濾液的研究」，中國給水排水，第27卷，第15期，第16-20頁(2011)。