Page 552 - Polymer-based Nanocomposites for Energy and Environmental Applications
P. 552

Polymer nanocomposite application                                 505

           [126] Su Q, Pan BC, Pan BJ, Zhang QR, Zhang WM, Lv L, et al. Fabrication of polymer-
                supported nanosized hydrous manganese dioxide (HMO) for enhanced lead removal
                from waters. Sci Total Environ 2009;407(21):5471–7.
           [127] Jang JH. Surface chemistry of hydrous ferric oxide and hematite as based on their reac-
                tions with Fe(II) and U(VI) [Ph.D. dissertation] University Park, PA: The Pennsylvania
                State University; 2004.
           [128] Pierce ML, Moore CB. Adsorption of as(III) and as(V) on amorphous iron hydroxide.
                Water Res 1982;6:1247–53.
           [129] Pan BC, Pan BJ, Zhang WM, Zhang QJ, Zhang QR, Jiang PJ, Zhang QX. Chinese Patent:
                CN 200710191355.3 (2007).
           [130] Zhang QR, Pan BC, Pan BJ, Zhang WM, Jia K, Zhang QX. Selective sorption of lead,
                cadmium and zinc ions by a polymeric cation exchanger containing nano-Zr(HPO 3 S) 2 .
                Environ Sci Technol 2008;42:4140–5.
           [131] Badruddoza AZM, Tay ASH, Tan PY, Hidajat K, Uddin MS. Carboxymethyl-
                cyclodextrin conjugated magnetic nanoparticles as nano-adsorbents for removal of cop-
                per ions: synthesis and adsorption studies. J Hazard Mater 2011;185(2–3):1177–86.
                                        +3
           [132] Zelmanov G, Semiat R. Iron (Fe )oxide/hydroxide nanoparticles-based agglomerates
                                              +6
                suspension as adsorbent for chromium (Cr ) removal from water and recovery. Sep Purif
                Technol 2011;80:330–7.
           [133] Xu G, Wang J, Li C. Preparation of hierarchically nanofibrous membrane and its high
                adaptability in hexavalent chromium removal from water. Chem Eng J 2012;198-
                199:310–7.
           [134] Bhaumik M, Setshedi K, Maity A, Onyango MS. Chromium(VI) removal from water
                using fixed bed column of polypyrrole/Fe 3 O 4 nanocomposite. Sep Purif Technol
                2013;110:11–9.
           [135] Wu N, Wei H, Zhang L. Efficient removal of heavy metal ions with biopolymer template
                synthesized mesoporous titania beads of hundreds micrometers in size. Environ Sci
                Technol 2012;46:419–25.


           Further reading

                                      ¸
                                ¸
           [1] G€ urses A, Doğar C, Yalcin M, Acikyildiz M, Bayrak R, Karaca S. The adsorption kinetics
              of the cationic dye, methylene blue, onto clay. J Hazard Mater B 2006;131:217–28.
           [2] Utracki LA, Sepehr M, Boccaleri E. Synthetic, layered nanoparticles for polymeric
              nanocomposites (PNCs). Polym Adv Technol 2007;18:1–37.
           [3] Cai LF, Huang XB, Rong MZ, Ruan WH, Zhang MQ. Fabrication of nanoparticle/polymer
              composites by in situ bubble-stretching and reactive compatibilization. Macromol Chem
              Phys 2006;207:2093–102.
           [4] Li X, Wang D, Cheng G, Luo Q, An J, Wang Y. Preparation of polyaniline-modified TiO 2
              nanoparticles and their photocatalytic activity under visible light illumination. Appl Catal
              B Environ 2008;81(3–4):267–73.
           [5] Liaw W, Chen K. Preparation and characterization of poly(imide siloxane) (PIS)/titania
              (TiO 2 ) hybrid nanocomposites by sol–gel processes. Eur Polym J 2007;43(6):2265–78.
           [6] Pan BJ, Wu J, Pan BC, Lv L, Zhang WM, Xiao L, et al. Development of polymer-based
              nanosized hydrated ferric oxides (HFOs) for enhanced phosphate removal from waste efflu-
              ents. Water Res 2009;43(17):4421–9.
   547   548   549   550   551   552   553   554   555   556   557