Nanoparticle Transport, Aggregation, and Deposition  291

         39. Smoluchowski, M., Versuch einer Mathematischen Theorie der Koagulations- Kinetik
            Kolloider Losungen. 1917. 92: p. 129.
         40. Han, M., and D.F. Lawler, Interactions of two settling spheres: settling rates and
            collision efficiency. J. Hydraulic Engrg.-ASCE, 1991. 117(10): p. 1269–1289.
         41. Veerapaneni, S., and M.R. Wiesner, Particle deposition to an infinitely permeable
            surface: dependence of deposit morphology on particle size. Journal of Colloid and
            Interface Science, 1996. 162(1): p. 110–122.
         42. Veerapaneni, S., and M.R. Wiesner, Hydrodynamics of fractal aggregates with radi-
            ally varying permeability. Journal of Colloid and Interface Science, 1996. 177:
            p. 45–57.
         43. Brant, J.A., et al., Characterizing the impact of preparation method on fullerene
            cluster structure and chemistry. Langmuir, 2006. 22: p. 3878–3885.
         44. Ruoff, R.S., et al., Solubility of C 60 in a variety of solvents. Journal of Physical
            Chemistry, 1993. 97: p. 3379–3383.
         45. Marcus, Y., et al., Solubility of C 60 fullerene. Journal of Physical Chemistry B, 2001.
            105: p. 2499–2506.
         46. Nakamura, E., and H. Isobe, Functionalized fullerenes in water. The first 10 years
            of their chemistry, biology, and nanoscience. Accounts of Chemical Research, 2003.
            36(11): p. 807–815.
         47. Barnard, A.S., and L.A. Curtiss, Prediction of TiO 2 nanoparticle phase and shape
            transitions controlled by surface chemistry. Nano Letters, 2005. 5(7): p. 1261–1266.
         48. Georgakilas, V., et al., Supramolecular self-assembled fullerene nanostructures.
            Proceedings of the National Academy of Sciences, 2002. 99(8): p. 5075–5080.
         49. Guo, Z.-X., et al., Nanoscale aggregation of fullerene in nafion membrane. Langmuir,
            2002. 18: p. 9017–9021.
         50. Natalini, B., et al., Chromatographic separation and evaluation of the lipophilicity
            by reversed-phase high performance liquid chromotography of fullerene-C 60 deriva-
            tives. Journal of Chromatography A, 1999. 847: p. 339–343.
         51. Moraru, V., N. Lebovka, and D. Shevchenko, Structural transitions in aqueous sus-
            pensions of natural graphite. Colloids and Surfaces  A: Physicochemical and
            Engineering Aspects, 2004. 242(1–3): p. 181–187.
         52. Angelini, G., et al., Study of the aggregation properties of a novel amphilic C 60
            fullerene derivative. Langmuir, 2001. 17: p. 6404–6407.
         53. Guldi, D.M., et al., Ordering fullerene materials at nanometer dimensions. Accounts
            of Chemical Research, 2005. 38(1): p. 38–43.
         54. Fauconnier, N., et al., Thiolation of maghemite nanoparticles by dimercaptosuccinic
            acid. Journal of Colloid and Interface Science, 1997. 194(2): p. 427–433.
         55. Bellona, C., et al., Factors affecting the rejection of organic solutes during NF/RO
            treatment—a literature review. Water Research, 2004. 38: p. 2795–2809.
         56. Hsu, J.-P. and Y.-C. Kuo, An algorithm for the calculation of the electrostatic potential
            distribution of ion-penetrable membranes carrying fixed charges. J. Colloid Interface
            Sci., 1995. 171: p. 483–489.
         57. Hunter, R.J., Zeta Potential in Colloid Science: Principles and Applications. 1981,
            London: Academic Press.
         58. O’Melia, C.R., Particle-particle interactions in aquatic systems. Colloids and Surfaces,
            1989. 39: p. 255.
         59. Happel, J., Viscous flow in multiparticle systems: slow motion of fluids relative to beds
            of spherical particles. A.I.Ch.E.,J, 1958. 4(2): p. 197–201.
         60. Derjaguin, B.V., and L.D. Landau, Theory of the stability of strongly charged lyopho-
            bic sols and of the adhesion of strongly charged particles in solutions of electrolytes.
            Acta Physicochim. URSS, 1941. 14: p. 733–762.
         61. Elimelech, M., and C.R. O’Melia, Effect of particle size on collision efficiency in the
            deposition of Brownian particles with electrostatic energy barriers. Langmuir, 1990.
            6: p. 1153–1163.
         62. Ryan, J.N., and M. Elimelech, Colloid mobilization and transport in groundwater.
            Colloids and Surfaces A: Physicochemical and Engineering Aspects, 1996. 107:
            p. 1–56.
         63. O’Melia, C.R., ed. Kinetics of Colloid Chemical Processes in Aquatic Systems. ed.
            W. Stumm. 1990, John Wiley & Sons, Inc.: New York.