Abstract
This study evaluated the filtration of engineered nanoparticles of fullerene and copper oxide (CuO) from water by using surface-modified microsized filters. The surfaces of microsized filters of cellulose acetate and glass fibers were coated with cationic and anionic surfactants to give them positively and negatively charged surfaces, respectively. Uncoated microfilters removed 30 % of a fullerene suspension, while no nanosized CuO suspension was removed. Cationic surfactant-coated filters enhanced the removal efficiency up to 70 % for the fullerene suspension, while the anionic surfactant-coated filters could not remove fullerene at all. The positively charged filters with cationic surfactant coating could easily adsorb negatively charged fullerenes on their surfaces. However, none of the surfactant-coated filters removed the CuO nanoparticles because the nanoparticles were not affected by the electrical charge of the filtration medium. The Hamaker constants of nanoparticles interacting with the filter materials in water were calculated to study these interactions. The Hamaker constant of fullerene interacting with cellulose acetate in water, 4.68E − 21 J, was higher than that of interacting with quartz in water, 2.59E − 21 J. However, the Hamaker constants of CuO interacting with quartz and cellulose acetate in water were both negative values, implying repulsive van der Waals interactions. The curves of potential energy of interaction between nanoparticles and the various filter media implied that the nanoparticles were very stable in water, and so, natural deposition of nanoparticles on the filters would not occur. Therefore, electrical bonding and hydrophobic interactions were the forces dominating fullerene removal by positively charged filters.
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Bergstrom, L. (1997). Hamaker constants of inorganic materials. Advances in Colloid and Interface Science, 70, 125–169.
Carrillo-Carrión, C., Lucena, R., Cárdenas, S., & Valcárcel, M. (2007). Surfactant-coated carbon nanotubes as pseudophases in liquid-liquid extraction. Analyst, 132, 551–559.
Elimelech, M., Gregory, J., Jia, X., & Williams, R. A. (1995). Particle deposition and aggregation: measurement, modelling and simulation. MA, USA: Butterworth-Heineman.
Hiemenz, P. C., & Rajagopalan, R. (1997). Principles of colloid and surface chemistry. New York: Marcel Dekker, Inc.
Holbrook, R. D., Kline, C. N., & Filliben, J. J. (2010). Impact of source water quality on multiwall carbon nanotube coagulation. Environmental Science and Technology, 44, 1386–1391. doi:10.1021/es902946j.
Hwang, Y., Kim, D., Ahn, Y. T., Moon, C. M., & Shin, H. S. (2012). Recovery of ammonium salt from nitrate-containing water by iron nanoparticles and membrane contactor. Environmental Engineering Research, 17, 111–116. doi:10.4491/eer.2012.17.2.111.
Jassby, D., Chae, S. R., Hendren, Z., & Wiesner, M. (2010). Membrane filtration of fullerene nanoparticle suspensions: effects of derivatization, pressure, electrolyte species and concentration. Journal of Colloid and Interface Science, 346, 296–302.
Kang, P. K., & Shah, D. O. (1997). Filtration of nanoparticles with dimethyldioctadecylammonium bromide treated microporous polypropylene filters. Langmuir, 13, 1820–1826.
Kim, S., Lee, K. S., Zachariah, M. R., & Lee, D. (2010). Three-dimensional off-lattice Monte Carlo simulations on a direct relation between experimental process parameters and fractal dimension of colloidal aggregates. Journal of Colloid and Interface Science, 344, 353–361. doi:10.1016/j.jcis.2010.01.008.
Lin, Y. T., Sung, M., Sanders, P. F., Marinucci, A., & Huang, C. P. (2007). Separation of nano-sized colloidal particles using cross-flow electro-filtration. Separation and Purification Technology, 58, 138–147.
Ma, X., Wigington, B., & Bouchard, D. (2010). Fullerene C60: surface energy and interfacial interactions in aqueous systems. Langmuir, 26, 11886–11893. doi:10.1021/la101109h.
Petosa, A. R., Jaisi, D. P., Quevedo, I. R., Elimelech, M., & Tufenkji, N. (2010). Aggregation and deposition of engineered nanomaterials in aquatic environments: role of physicochemical interactions. Environmental Science and Technology, 44, 6532–6549.
Tian, J. Y., Ernst, M., Cui, F., & Jekel, M. (2013). Effect of particle size and concentration on the synergistic UF membrane fouling by particles and NOM fractions. Journal of Membrane Science, 446, 1–9.
Van Oss, C. J. (2006). Interfacial forces in aqueous media. Boca Raton: CRC Press.
Yang, K., Jing, Q., Wu, W., Zhu, L., & Xing, B. (2010). Adsorption and conformation of a cationic surfactant on single-walled carbon nanotubes and their influence on naphthalene sorption. Environmental Science and Technology, 44, 681–687. doi:10.1021/es902173v.
Zhang, Y., Chen, Y., Westerhoff, P., & Crittenden, J. C. (2008). Stability and removal of water soluble CdTe quantum dots in water. Environmental Science and Technology, 42, 321–325.
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This research was supported by the Basic Science Research Program through the National Research Foundation of Korea (NRF) funded by the Ministry of Education, Science and Technology (2010-0007799).
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Jeong, SW., Kim, H. Filtration of fullerene and copper oxide nanoparticles using surface-modified microfilters. Environ Monit Assess 186, 5855–5864 (2014). https://doi.org/10.1007/s10661-014-3824-4
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DOI: https://doi.org/10.1007/s10661-014-3824-4