Page 230 - Polymer-based Nanocomposites for Energy and Environmental Applications
P. 230
202 Polymer-based Nanocomposites for Energy and Environmental Applications
[126] Guo N, Liang Y, Lan S, Liu L, Zhang J, Ji G, et al. Microscale hierarchical three-
dimensional flowerlike TiO 2 /PANI composite: synthesis, characterization, and its
remarkable photocatalytic activity on organic dyes under UV-light and sunlight irradia-
tion. J Phys Chem C 2014;118:18343–55.
[127] Pei Z, Ding L, Lu M, Fan Z, Weng S, Hu J, et al. Synergistic effect in polyaniline-hybrid
defective ZnO with enhanced photocatalytic activity and stability. J Phys Chem C
2014;118:9570–7.
[128] Swallow KC, Hume DN, Morel FMM. Sorption of copper and lead by hydrous ferric
oxide. Environ Sci Technol 1980;14:1326.
[129] Ansari MO, Khan MM, Ansari SA, Lee J, Cho MH. Visible light-driven photocatalytic
and photoelectrochemical studies of Ag-SnO 2 nanocomposites synthesized using an
electrochemically active biofilm. RSC Adv 2014;4:26013–21.
[130] Ramalingam RJ, Arunachalam P, Radhika T, Anju KR, Nimitha KC, Al-Lohedan HA.
Surface and electrochemical characterization of N-Fe-doped TiO 2 nanoparticle prepared
by hydrothermal and facile electro-deposition method for visible light driven pollutant
removal. Int J Electrochem Sci 2017;12:797–811.
[131] Ansari MO, Khan MM, Ansari SA, Raju K, Lee J, Cho MH. Enhanced thermal stability
under DC electrical conductivity retention and visible light activity of ag/TiO 2 @ poly-
aniline nanocomposite film. ACS Appl Mater Interfaces 2014;6:8124–33.
[132] Fan M, Boonfueng T, Xu Y, Axe L, Tyson TA. Modeling Pb sorption to microporous
amorphous oxides as discrete particles and coatings. J Colloid Interface Sci 2005;281:39.
[133] Trivedi P, Axe L, Tyson TA. XAS studies of Ni and Zn sorbed to hydrous manganese
oxide. Environ Sci Technol 2001;35:4515–21.
[134] Kawashima M, Tainaka Y, Hori T, Koyama M, Takamatsu T. Phosphate adsorption onto
hydrous manganese(IV) oxide in the presence of divalent cations. Water Res
1986;20:471–5.
[135] Pan BC, Zhang QR, Du W, Zhang WM, Pan BJ, Zhang QJ, et al. Selective heavy metals
removal from waters by amorphous zirconium phosphate: behavior and mechanism.
Water Res 2007;41:3103–11.
2+
2+
[136] Jia K, Pan BC, Zhang QR, Zhang WM, Jiang PJ, Hong CH, et al. Adsorption of Pb ,Zn ,
and Cd 2+ from waters by amorphous titanium phosphate. J Colloid Interface Sci
2008;318:160–6.
[137] Raynie DE. Modern extraction techniques. Anal Chem 2004;76:4659–64.
[138] Pan BC, Zhang QR, Zhang WM, Pan BJ, Du W, Lv L, et al. Highly effective removal of
heavy metals by polymer-based zirconium phosphate: a case study of lead ion. J Colloid
Interface Sci 2007;310:99–105.
[139] Jang JH. Surface chemistry of hydrous ferric oxide and hematite as based on their reac-
tions with Fe(II) and U(VI) [PhD Dissertation]. University Park, PA: The Pennsylvania
State University; 2004.
[140] Pierce ML, Moore CB. Adsorption of As(III) and As(V) on amorphous iron hydroxide.
Water Res 1982;16:1247–53.
[141] Dzombak DA, Morel FMM. Surface complexation modeling: hydrous ferric oxide. New
York: Wiley; 1990.
[142] Gong T, Zhou Y, Sun L, Liang W, Yang J, Shuang S, et al. Effective adsorption of phe-
nolic pollutants from water using β-cyclodextrin polymer functionalized Fe 3 O 4 magnetic
nanoparticles. RSC Adv 2016;6:80955–63.
[143] Sarkar M, Acharya PK. Use of fly ash for the removal of phenol and its analogues from
contaminated water. Waste Manag 2006;26:559–70.
