[1] F. Gottschalk, B. Nowack, The release of engineered nanomaterials to the environment, J. Environ. Monit., 13 (2011) 1145-1155.
[2] P. Andujar, S. Lanone, P. Brochard, J. Boczkowski, Effets respiratoires des nanoparticules manufacturées, Rev. Mal. Respir., 26 (2009) 625–637.
[3] D. Palomino, Nanoparticules: Risques pour l’homme et l’environnement, GWA, 89 (2009) 979–990.
[4] C. Santaella, M. Auffan, A. Thiery, J.-Y. Bottero, Reproduire un écosystème pour évaluer l’impact des nanoparticules, Biofutur, 347 (2013) 46–49.
[5] A. Simon-Deckers, Effets biologiques de nanoparticules manufacturées: influence de leurs caractéristiques, AgroParisTech, 2008.
[6] R. Hischier, T. Walser, Life cycle assessment of engineered nanomaterials: State of the art and strategies to overcome existing gaps, Sci. Total Environ., 425 (2012) 271–282.
[7] M. Troester, H.-J. Brauch, T. Hofmann, Vulnerability of drinking water supplies to engineered nanoparticles, Water Res., 96 (2016) 255–279.
[8] N. Wu, Y. Wyart, J. Rose, B. Angeletti, P. Moulin, Application of membrane processes in fractionation of elements in river water, Water Sci. Technol., 72 (2015) 2278-2291.
[9] D. A. Ladner, M. Steele, A. Weir, K. Hristovski, P. Westerhoff, Functionalized nanoparticle interactions with polymeric membranes, J. Hazard. Mater., 211 (2012) 288–295.
[10] F. Springer, S. Laborie, C. Guigui, Removal of SiO2 nanoparticles from industry wastewaters and subsurface waters by ultrafiltration: Investigation of process efficiency, deposit properties and fouling mechanism, Sep. Purif. Technol., 108 (2013) 6–14.
[11] T.E. Abbott Chalew, G.S. Ajmani, H. Huang, K.J. Schwab, Evaluating Nanoparticle Breakthrough during Drinking Water Treatment, Environ. Health Perspect., Aug. 2013.
[12] J. Decarolis, S. Hong, J. Taylor, Fouling behavior of a pilot scale inside-out hollow fiber UF membrane during dead-end filtration of tertiary wastewater, J. Membr. Sci., 191 (2001) 165–178.
[13] E. Barbot, P. Dussouillez, J.Y. Bottero, P. Moulin, Coagulation of bentonite suspension by polyelectrolytes or ferric chloride: Floc breakage and reformation, Chem. Eng. J., 156 (2010) 83–91.
[14] C. Henry, J.A. Brant, Mechanistic analysis of microfiltration membrane fouling by buckminsterfullerene (C60) nanoparticles, J. Membr. Sci., 415 (2012) 546–557.
[15] K.W. Trzaskus, W.M. de Vos, A. Kemperman, K. Nijmeijer, Towards controlled fouling and rejection in dead-end microfiltration of nanoparticles – Role of electrostatic interactions, J. Membr. Sci., 496 (2015) 174–184.
[16] K. Trzaskus, M. Elshof, A. Kemperman, K. Nijmeijer, Understanding the role of nanoparticle size and polydispersity in fouling development during dead-end microfiltration, J. Membr. Sci., 516 (2016) 152–161.
[17] K. W. Trzaskus, A. Zdeb, W. M. de Vos, A. Kemperman, K. Nijmeijer, Fouling behavior during microfiltration of silica nanoparticles and polymeric stabilizers, J. Membr. Sci., 505 (2016) 205–215.
[18] D. Jassby, S.-R. Chae, Z. Hendren, M. Wiesner, Membrane filtration of fullerene nanoparticle suspensions: Effects of derivatization, pressure, electrolyte species and concentration, J. Colloid Interface Sci., 346 (201) 296–302.
[19] N. Wu, Y. Wyart, L. Siozade, G. Georges, P. Moulin, Characterization of ultrafiltration membranes fouled by quantum dots by confocal laser scanning microscopy, J. Membr. Sci., 470 (2014) 40–51.
[20] J. Hermia, Constant pressure blocking filtration laws - Application to power-law non-newtonian fluids, Trans IChemE, 60 (1982) 111–120.
[21] A. Charfi, Etude d’un procédé membranaire de traitement des eaux usées: effet des paramètres biotiques et abiotiques sur le colmatage de la membrane, Université de Carthage, 2014.
[22] V.V. Tarabara, I. Koyuncu, M.R. Wiesner, Effect of hydrodynamics and solution ionic strength on permeate flux in cross-flow filtration: direct experimental observation of filter cake cross-sections, J. Membr. Sci., 241 (2004) 65–78.