专论与综述

生物吸附法去除水中重金属离子

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  • 同济大学环境工程学院, 上海 200092
李霞(1979- ),同济大学环境学院在读硕士生.

收稿日期: 2003-01-14

  网络出版日期: 2010-10-01

Removal of heavy metal in water bodies by biosorption

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  • School of Environmental Science and Engineering, Tongji University, Shanghai 200092, China

Received date: 2003-01-14

  Online published: 2010-10-01

摘要

生物吸附作为一种有效的去除水中重金属的方法引起人们的极大关注.近几年虽然提出了许多吸附模型,但生物体的吸附机理尚不完全清楚.生物吸附过程受生物体本身的性质、处理水的种类、离子强度、pH、反应动力学、反应设备等因素的影响.由于生物体在吸附和脱吸过程中具有非常好的可逆性,并且这种生物体大量存在,因此在水处理领域具有非常好的应用前景.作者主要介绍了近几年国外生物吸附法在水处理方面的研究成果.

关键词: 生物吸附; 重金属; 模型

本文引用格式

李霞, 李风亭, 张冰如 . 生物吸附法去除水中重金属离子[J]. 工业水处理, 2004 , 24(3) : 1 -4 . DOI: 10.11894/1005-829x.2004.24(3).1

Abstract

Biosorption has attracted people′s attention as an effective method for the treatment of metal-bearing wastewater. In recent years, many models of the biosorption performance have been presented, but the mechanism of biosorption is not clearly understood. The process is affected by the properties of organism, the types of water bodies, ionic strength, pH, reaction kinetics and equipment of reaction. Due to good reversibility in the process of biosorption and desorption and the abundant amount of the biomass, the application of this process to water treatment is promising. The author mainly introduces the recent research achievement of biosorption.

Key words: biosorption; heavy metal; models

参考文献

[1] Kratochvil D, et al. Removal of trivalent and hexavalent chromium by seaweed biosorbent [J]. Envion. Sci. Technol., 1998, 32:2 693 -2 698
[2] Totura G. Innovative uses of speciality ion exchange resins provide new cost-effective options for metals removal [J]. Environ. Prog.,1996, 15:208
[3] 吴涓,等.重金属生物吸附的研究进展[J].离子交换与吸附,1998,14(2):180-187
[4] 刘刚,李清彪.重金属生物吸附的基础和过程研究[J].水处理技术,2002,28(1):17-21
[5] Veglio F, et al. Experimental Study and Simulation on the Biosorption of Copper ( Ⅱ ) in Membrane Reactors i A Preliminary Study[J]. Ind. Eng. Chem. Res., 2000, 39:2 480-2 484
[6] Holan Z R, et al. 1. Cd Biosorption by Saccharomyces Cerevisiae[J]. Biotechnol. Bioeng., 1993, 41:819-825
[7] Yeoung Sang Yun, et al. Biosorption of Trivalent Chromium on the Brown Seaweed Biomass[J]. Environ. Sci. Technol., 2001, 35:4 353-4 358
[8] 维戈利奥F,等.综述回收金属的生物吸附法[J].国外金属选矿,1998, (12) :27- 35
[9] Kuyueak N, et al. A method of metal removal[J]. Biotech. and Bioeng, 1989, 33:809
[10] Hui Niu, et al. Enhancement of gold-cyanide biosorption by Lcysteine[M], ibid, 1999, 493-502
[11] Sike Schiewer, et al. Ionic Strength and Electrostatic Effects in Biosorption of Protons[J]. Environ. Sci. Technol., 1997, 31:1 863 - 1 871
[12] Westall J C, et al. Models for Association of Metal Ions with Heterogeneous Environmental Sorbents: Ⅰ. Complexation of Co ( Ⅱ )by Leonardite Humic Acid as a Function of pH and NaC1O4 Concentration[J]. Environ. Sci. Technol., 1995, 29:951-959
[13] Cabaniss S E, et al. Geochim. Cosmochim. Copper binding by Nanofiltration membrane technology and its developmentdissolved organic matter: Suwannee River fulvic acid equilibria [J ].Geochim. Cosmochim. Acta, 1988, 52: 185- 193
[14] Bartschat B M, et al. Oligoelectrolite model for cation binding by humic substances[J]. Environ. Sci. Technol., 1992, 26:284- 294
[15] Xue H B, et al. The binding of heavy metals to algal surfaces [J].Water Res., 1988, 22:917 -926
[16] Tipping E, et al. The Complexation of Protons, Aluminium and Calcium bu Aquatic: Humic Substances: A Model Incorporating Binding Heterogeneity and Macroionic Effects[J]. Water Res., 1988, 22:597-611
[17] De Wit J C M, et al. Proton binding to humic substances. A. Electrostaic effects[J].Environ.Sci.Technol.,1993,27:2005-2014
[18] 叶锦韶,等.重金属的生物吸附研究进展[J].城市环境与城市生态,2001,14(3):30-32
[19] 任洪强,陈坚,伦世仪.重金属生物吸附剂的应用研究现状[J].生物技术,2000,10(1):33-36
[20] Veglio F, et al. Experimental Study and Simulation on the Biosorption of Copper( Ⅱ ) in Membrane Reactors: A Preliminary Study[J].Ind. Eng. Chem. Res., 2000, 39: 2 480 - 2 484

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