[1] Steinle D.E., Reinhard M. Nanofiltration for trace organic contaminant removal: Structure, solution, and membrane fouling effects on the rejection of perfluoro chemicals. Environmental Science and Technology, 2008,42(3):5292-5297
[2] Wu M., Sun D.D. Characterization and reduction of membrane fouling during nanofiltration of semiconductor indium phosphide(InP) wastewater. Journal of Membrane Science, 2005,259(1-2):135-144
[3] Wu M., Sun D.D., Tay J.H. Effect of operating variables on rejection of indium using nanofiltration membranes. Journal of Membrane Science, 2004,240(1-2):105-111
[4] Kabsch K. Effect of Al coagulant type on natural organic matter removal efficiency in coagulation/ultrafiltration process. Desalination, 2005,185(1-3):327-333
[5] Tang C.Y., Kwon Y.N., Leckie J.O. Characterization of humic acid fouled reverse osmosis and nano?ltration membranes by transmission electron microscopy and streaming potential measurements. Environmental Science and Technology, 2007,41(3):942-949
[6] Kimura K., Hane Y., Watanabe Y. Effect of pre-coagulation on mitigatingirre-versible fouling during ultrafiltration of a surface water. Water Science and Technology,2005,51(6-7):93-100
[7] Listiarini K., Sun D. D., Leckie J. O., et al. Organic fouling of nanofiltration membranes: Evaluating the effects of humic acid, calcium, alum coagulant and their combinations on the specific cake resistance. Journal of Membrane Science, 2009,332(1-2):56-62
[8] Tang C.Y., Fu Q.S., Criddle C.S., et al. Effect of flux (transmembrane pressure) and membrane properties on fouling and rejection of reverse osmosis and nanofiltration membranes treating perfluorooctane sulfonate containing wastewater. Environmental Science and Technology, 2007,41(6):2008-2014
[9] Tang C.Y., Kwon Y.N., Leckie J.O. Characterization of humic acid fouled reverse osmosis and nanofiltration membranes by transmission electron microscopy and streaming potential measurements. Environmental Science and Technology, 2007,290(1-2):942-949
[10] 刘百仓,黄尔,鲁金凤, 等. 混凝工艺水力条件的优化与絮体尺寸的研究. 环境工程学报, 2010,3(9):1968-1972 Liu B.C., Huang R., Lu J.F., et al. Optimization of hydrodynamic conditions in coagulation process and study of floc size characteristics. Chinese Journal of Environmental Engineering, 2010,3(9): 1968-1972(in Chinese)
[11] Schippers J.C., Verdouw J. The modified fouling index, a method of determining the fouling characteristics of water. Desalination, 1980,32(3):137-148
[12] 王洪杰,王毅力,Dentel Steven K. 调理污泥在剪切测试过程中的絮体与聚集体之间的转化研究. 环境工程学报,2010,4(12):2662-2668 Wang H.J., Wang Y.L., Dentel S. K. Study on transformation between flocs and aggregates in conditioned anaerobic digested sludge(ADS) suspensions during a shear test. Chinese Journal of Environmental Engineering, 2010,4(12):2662-2668(in Chinese)
[13] Kim S.H., Moon B.H., Lee H.I. Effects of pH and dosage on pollutant removal and floc structure during coagulation. Journal of Microbial Chemistry, 2001,81(2):197-203
[14] Wang J., Guan J.,Santiwong S.R., et al. Effect of aggregate characteristics under different coagulation mechanisms on microfiltration membrane fouling. Desalination, 2010,258(1-3):19-27
[15] Hong S.K., Elimelech M. Chemical and physical aspects of natural organic matter(NOM) fouling of nanofiltration membranes. Journal of Membrane Science, 1997,132(2):159-181
[16] Jarusutthirak C., Mattaraj S., Jiraratananon R. Influence of inorganic scalants and natural organic matter on nanofiltration membrane fouling. Journal of Membrane Science, 2007,287(1):138-145
[17] Guan J., Amal R., Waite T. Effect of aggregate size and structure on specific resistance of biosolids filter cakes. Water Science and Technology,2001,44(10):215-220
[18] Lee S.A., Fane A. G., Amal R., et al. The effect of floc size and structure on specific cake resistance and compressibility in deadend microfiltration. Separation Science and Technology, 2003,38(4):869-887
[19] Cho M.H., Lee C.H., Lee S. Influence of floc structure on membrane permeability in the coagulation-MF process. Water Science and Technology, 2005 ,51(6-7):143-150