富油微藻在不同污水中的培养与应用研究进展
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摘要
近年来,全球范围的能源短缺以及二氧化碳排放引起的温室效应等问题,已经严重威胁到人类的可持续发展。通过培养富油微藻,既能减少二氧化碳,又能增加可再生能源供给,缓解社会发展的压力。微藻的生长需要大量吸收氮磷,其生长特性恰好能有益于污水处理,在减少污水厂处理运行成本的同时,还能收获高附加值藻细胞。因此,将微藻培养与污水处理相结合,具有潜在应用前景。本文旨在通过分析不同类型污水中微藻的生长情况,为今后研究废水培养微藻的适宜条件做出有意义的指导。
引文
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[22]吕素娟,张维,彭小伟,等.城市生活废水用于产油微藻培养[J].生物工程学报,2011,27(3):445-452.
[23]Canizares R O,Rivas L,Montes C,et al.Aerated swine-wastewater treatment with K-carrageenan-immobilized Spirulina maxima[J].Bioresource Technology,1994,47(1):89-91
[24]李君荣,申婷,胡蕾.蛋白核小球藻处理猪场废水的效果观察[J].家畜生态学报,2012,33(5):80-82
[25]张建民,张倩,赵宏,等.利用不同浓度啤酒废水培养塔胞藻的生物学效应研究[J].海洋湖沼通报,2008,4:63-68.
[26]Chinnasamy S,Bhatnagar A,Hunt R W,Das K.C.Microalgae cultivation in a wastewater dominated by carpet mill effluents for biofuel applications[J].Bioresource Technology,2010,101(9):3097-3105.
[27]杨静.造纸废水培养富油微藻的研究[J].生物质化学工程,2012,45(4):64-65.
[28]孙雪飞.维生素B2废水培养富油微藻及其膜浓缩分离[D].武汉:武汉工程大学,2012.
[2]赖雅琦,赵海洋,周志军等.废水养殖微藻的资源化利用研究进展[J].水处理技术,2013,39(10):12-17.
[3]Gonzalez L E,Canizares R O,Baena S.Efficiency of ammonia and phosphorus removal from a Colombian agroindustrial wastewater by the microalgae Chlorella vulgaris and Scenedesmus dimorphus[J].Bioresource Technology,1997,60(3):259-262.
[4]Valderrama L T,Del Campo C M,Rodriguez CM,et al.Treatment of recalcitrant wastewater from ethanol and citric acid production using the microalga Chlorella vulgaris and the macrophyte Lemna minuscula[J].Water Research,2002,36(17):4185-4192.
[5]Wong M H,Pak D C.Removal of Cu and Ni by free and immobilized microalgae[J].Biomedical and environmental sciences:BES,1992,5(2):99-108.
[6]支田田,程丽华,徐新华,等.藻类去除水体中重金属的机理及应用[J].化学进展,2011,23(8):1782-1794.
[7]Wilkinson S C,Goulding K H,Robinson P K.Mercury accumulation and volatilization in immobilized algal cell systems[J].Biotechnology Letters,1989,11(12):861-864.
[8]杨婷,任春英,李娟等.城市生活污水中富油微藻的筛选[J].中国农业科技导报,2015,17(3):144-151.
[9]Pittman J K,Dean A P,Osundeko O.The potential of sustainable algal biofuel production using wastewater resources[J].Bioresour.Technol,2011,102(1):17-25.
[10]Park J B K,Craggs R J,Shilton A N.Wastewater treatment high rate algal ponds for biofuel production[J].Bioresour.Technol,2011,102(1):35-42.
[11]Feng Y,Li C,Zhang D.Lipid production of Chlorella vulgaris cultured in artificial wastewater medium[J].Bioresour.Technol,2011,102(1):101-105.
[12]胡洪营,李鑫.利用污水资源生产微藻生物柴油的关键技术及潜力分析[J].生态环境学报,2010,19(3):739-744.
[13]ASLAN S,KAPDAN I K.Batch kinetics of nitrogen and phosphorus removal from synthetic wastewater by algae[J].Ecological Engineering,2006,28:64-70.
[14]许云,梁文思,刘志嫒.2株微藻对养殖废水中氮磷去除率的影响[J].热带生物学报,2014,5(3):228-232.
[15]孟范平,宫艳艳,马冬冬.基于微藻的水产养殖废水处理技术研究进展[J].微生物学报,2009,49(6):691-696.
[16]陈红书.浅析我国水资源与水污染治理现状[J].云南环境科学,2003,22(3):66-69.
[17]杨从发.木薯酒精废糟培养小球藻工艺及灵芝生物转化小球藻的研究[D].无锡,江南大学,2009.
[18]朱国洪,刘振华,尹国,等.啤酒厂中段废水培养螺旋藻的研究[J].广西轻工业,2000,3:35-38.
[19]郑爱榕,蔡阿根,许伟斌,等.光合细菌和螺旋藻对啤酒废水的净化与利用研究[J].环境科学学报,1999,19(1):23-28.
[20]周连宁,王波.利用工业废水培养小球藻的水之净化研究[J].安徽农业科学,2013,41(34):13325-13329.
[21]Li X,Hu HY,Jia Y.Lipid accumulation and nutrient removal properties of a newly isolated freshwater microalga,Scenedesmus sp.LX1,growing in secondary effluent[J].New Biotechnology,2010,27(1):59-63.
[22]吕素娟,张维,彭小伟,等.城市生活废水用于产油微藻培养[J].生物工程学报,2011,27(3):445-452.
[23]Canizares R O,Rivas L,Montes C,et al.Aerated swine-wastewater treatment with K-carrageenan-immobilized Spirulina maxima[J].Bioresource Technology,1994,47(1):89-91
[24]李君荣,申婷,胡蕾.蛋白核小球藻处理猪场废水的效果观察[J].家畜生态学报,2012,33(5):80-82
[25]张建民,张倩,赵宏,等.利用不同浓度啤酒废水培养塔胞藻的生物学效应研究[J].海洋湖沼通报,2008,4:63-68.
[26]Chinnasamy S,Bhatnagar A,Hunt R W,Das K.C.Microalgae cultivation in a wastewater dominated by carpet mill effluents for biofuel applications[J].Bioresource Technology,2010,101(9):3097-3105.
[27]杨静.造纸废水培养富油微藻的研究[J].生物质化学工程,2012,45(4):64-65.
[28]孙雪飞.维生素B2废水培养富油微藻及其膜浓缩分离[D].武汉:武汉工程大学,2012.