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| Progress of Biological Hydrogen Production in Photosynthetic Bacteria Wastewater Treatment |
| ZHAO Wei1, ZHANG Guang-ming2,3 |
1. School of Municipal & Env. Engr., Harbin Institute of Technology, Harbin 150090, China;
2. School of Environment & Natural Resources, Renmin University of China, Beijing 100872, China;
3. State Environ. Protection Key Lab of Microorganism Application and Risk Control, Tsinghua University, Beijing 100872, China |
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Abstract Photosynthetic bacterial (PSB) hydrogen production technology can effectively combine solar energy utilization, hydrogen production, and pollutants removal from wastewater. It is one of the most potential hydrogen energy production technologies. By utilizing wastewater, the mechanism of PSB hydrogen production and the representative PSB with hydrogen production activity were analyzed. The main impacting factors and technology of PSB hydrogen production were summarized. The existing problems in research techniques were pointed out and the applications in the future were proposed.
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Received: 11 October 2012
Published: 25 December 2012
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[1] Das D, Nejat V T. Advances in biological hydrogen production processes. Internal January Hydrogen Energy, 2008, 3(1):6046-6057.
[2] Jutamas Kaewsuk, Worachat Thorasampan, Monthon Thanuttamavong, et al. Kinetic development and evaluation of membrane sequencing batch reactor (MSBR) with mixed cultures photosynthetic bacteria for dairy wastewater treatment. Journal of Environmental Management,2010,91(5):1161-1168.
[3] Haifeng Lu, Guangming Zhang, Xiao Dai, et al. Photosynthetic bacteria treatment of synthetic soybean wastewater: Direct degradation of macromolecules. Bioresource Technology, 2010, 101(19):672-674.
[4] Pavan K Soma, Martin Lo Y. Improvement of cultivation medium for enhanced production of coenzyme Q10 by photosynthetic Rhodospirillum rubrum. Biochemical Engineering Journal, 2010, 3 (51):160-166.
[5] Ken S, Masanori W, Yoshito S. Applications of photosynthetic bacteria for medical fields. Journal of Bioscience, 2005, 12 (3):472-478.
[6] Gest H, Ormerod J G, Ormerod K S. Photometabolism of R.rubrum. Light dependent dissimilation of organic compounds to carbon dioxide and molecular hydrogen by an anaerobic citric acid cycle. Archives of Biochemistry and Biophysics, 1962, 97(2):21-28.
[7] Michalski P, Ncholas D J D. Inhibition of nitrofenase by nitrite and nitric oxide in Rhodopseudomonas sphaeroidesf. sp. enitrificans. Arch Ficrobio1, 1987, 147(1):304-308.
[8] Tugba Keskin, Mona Abo-Hashesh, Patrick C Hallenbeck. Photo-fermentative hydrogen production from wastes. Bioresource Technology, 2011, 102(18):8557-8568.
[9] Schädler S, Burkhardt C, Hegler F, et al. Formation of cell-iron-mineral aggregates by phototrophic and nitrate-reducing anaerobic Fe (II)-oxidizing bacteria. Geo-microbiology Journal, 2009,26(2):93-103.
[10] 徐成斌,孟雪莲,马溪平,等.光合细菌的特性及其在产业中的应用,现代农业, 2010,9(1):91-92. Xu C B, Meng X L, Ma X P, et al. Photosynthetic bacteria characteristics and its application in the industry. Modern Agriculture, 2010, 9(1):91-92.
[11] Irwin D Kuntz,Paul A Loach,Melvin Calvin. Absorption changes in bacterial chromatophores. Biophysical Journal,1964,4(3): 227-249.
[12] Sonil Nanda,Prakash Kumar Sarangi,Jayanthi Abraham. Microbial bio-filtration technology for odour abatement: An introductory review. Journal of Soil Science and Environmental Management,2012,3(2):28-35.
[13] Meyer K M, Maca J L, Fulton J M, et al. Carotenoid biomarkers as an imperfect reflection of the anoxygenic phototrophic community in meromictic Fayetteville Green Lake. Geo-biology,2011,9(1):321-329.
[14] Derek S Hoare, Louise Hoare S. Hydrogen metabolism by Rhodomicrobium vannielii. Microbiology,1969,100(2):1124-1125.
[15] Schadler S, Burkhardt C, Hegler F,et al. Formation of cell-iron-mineral aggregates by phototrophic and nitrate-reducing anaerobic Fe (II)-oxidizing. Bacteria,2009,19(1):93-103.
[16] 王永忠,廖强,朱询. 产氢光合细菌分离鉴定及高产氢菌株筛选. 应用与环境生物学报,2008,14(5):673-677. Wang Y Z, Liao Q, Zu X. Isolation and identification of producing hydrogen photosynthetic bacteria and yield hydrogen strain screen. Applied and Environmental Biology, 2008, 14(5):673-677.
[17] Tongtong Chen,Dennis D Schulte,Richard K Koelsch,et al. Characteristics of phototrophic and non-phototrophic lagoons for swine manure. Biological Systems Engineering,2003,14(8):1285-1292.
[18] 胡吉军, 郭维强, 贾志国, 等. 混合菌群产氢特性研究. 应用与环境生物学报,2009,15(1):115-119. Hu J J, Guo W Q, Jia Z G, et al. Research of mixed flora hydrogen production. Applied and Environmental Biology, 2009, 15 (1):115-119.
[19] 贺静,马诗淳,黎霞,等. 能源微生物的研究进展. 中国沼气,2011,29(1):3-7. He J, Ma S C, Li X, et al. Energy microbial research progress, Chinese Biogas, 2011, 29 (1):3-7.
[20] 邓平,费良润,刘雪梅. 光合细菌产氢机制研究进展. 安徽农业科学,2008,36(15):6184-6186. Deng P, Fei L R, Liu X M, et al. Research progress of hydrogen production by photosynthetic bacteria mechanism. Agricultural Sciences, 2008, 36 (15):6184-6186.
[21] 张全国,范振山,王艳锦,等. 猪粪污水光合细菌制氢的影响因素,化工学报,2004, 55(S1):85-89. Zhang Q G, Fan J S, Wang Y J, et al. Research of the factors affecting pig manure sewage photosynthetic bacterial hydrogen production, Chemical Industry and Engineering, 2004, 55(S1):85-89.
[22] 安静. 光源和光谱对光合产氢菌群产氢工艺影响研究. 河南农业大学,2009,1-52. An J. Effect of the light source and the spectrum on PSB hydrogen production. Henan Agricultural University, 2009, 1-52.
[23] Tugba Keskin,Mona Abo-Hashesh,Patrick C,et al. Photo fermentative hydrogen production from wastes. Bioresource Technology, 2011,102 (18):8557-8568.
[24] 靳燕燕,周雪花,李遂亮,等. 光合细菌产氢系统产热速率的影响因素. 农业工程学报,2009,25(3):184-189. Jin Y Y, Zhou X H, Li S L, et al. The influencing factors of system heat production rate of hydrogen production by photosynthetic bacteria. Journal of Agricultural Engineering, 2009, 25 (3):184-189.
[25] 杨素萍,赵春贵,曲音波,等. 铁和镍对光合细菌生长和产氢的影响.微生物学报, 2003,02(1):132-137. Yang S P, Zhao C G, Qu Y B, et al. Effect of iron and nickel on the growth and hydrogen production of photosynthetic bacteria. Microbial Technology, 2003, 02 (1):132-137.
[26] 李晨林. 厌氧发酵生物制氢技术的研究. 郑州大学,2002,1-63. Li C L. Research of anaerobic fermentation of biological hydrogen production technology. Zhengzhou University, 2002,1-63.
[27] 杜金宇,王毅,赵民善,等. 葡萄糖基质对光合细菌光合产氢过程中菌体活性的影响. 农业工程学报,2010,52(1):92-96. Du J Y, Wang Y, Zhao M S, et al. Effect of glucose matrix bacterial activity of photosynthetic bacteria and hydrogen production. Journal of Agricultural Engineering, 2010, 52 (1):92-96.
[28] Wakayama T,Nakada E,Asada Y,et al. Effect of light/dark cycle on bacterial hydrogen production by Rhodobacter aphaeroides RV. From hour to second range. Apply Biochemistry Biotechnical,2003,8(4):431-440.
[29] Ito T,Nakashimada Y,Senba K,et al. Hydrogen and ethanol production from glycerol-containing wastes discharged after bio diesel manufacturing progress. Bioscience and Bioeng,2005,100(3):260-265.
[30] 王毅.光合细菌产氢基质代谢实验研究.河南农业大学,2009,1-57. Wang Y. Hydrogen production by photosynthetic bacteria matrix metabolism. Henan Agricultural University, 2009, 1-57.
[31] 刘敏,任南琪,丁杰, 等. 糖蜜、淀粉与乳品废水厌氧发酵法生物制氢. 环境科学, 2004,5(2):154-159. Liu M, Ren N Q, Ding J, et al. Molasses, starch and dairy wastewater anaerobic fermentation biohydrogen production. Environmental Science, 2004, 5 (2):154-159.
[32] 杨素萍,赵春贵, 曲音波, 等. 光合细菌产氢研究进展. 水生生物学报,2003,27(1): 85-91. Yang S P, Zhao C G, Qu Y B, et al. Research progress of hydrogen production by photosynthetic bacteria. Aquatic Biology, 2003, 27 (1): 85-91.
[33] 许之扬,严群,阮文权,等. 不同预处理对颗粒污泥利用厨余物产氢性能的影响. 安徽农业科学,2008,36(5):2002-2004. Xu Z Y, Yan Q, Ruan W Q, et al. Effect of different pretreatment granular sludge use property of the kitchen waste on hydrogen performance. Agricultural Sciences, 2008, 36 (5):2002-2004.
[34] 游少鸿,解庆林,马丽丽. 有机废水资源化技术——发酵产氢. 环境技术,2006,1(2):22-26. You S H, Xie Q L, Ma L L. Organic wastewater recycling technology—fermentation hydrogen production. Environmental Technology, 2006, 1(2):22-26. |
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