432                Polymer-based Nanocomposites for Energy and Environmental Applications

         [18] Kyzas GZ, Matis KA. Nanoadsorbents for pollutants removal: a review. J Mol Liq
             2015;203:159–68.
         [19] El Saliby I, Shon H, Kandasamy J, Vigneswaran S. Nanotechnology for wastewater treat-
             ment: in brief. In: Encyclopedia of Life Support System (EOLSS); 2008.
         [20] Dutta AK, Maji SK, Adhikary B. γ-Fe 2 O 3 nanoparticles: an easily recoverable effective
             photo-catalyst for the degradation of rose bengal and methylene blue dyes in the waste-
             water treatment plant. Mater Res Bull 2014;49:28–34.
         [21] Kurian M, Nair DS. Heterogeneous Fenton behavior of nano nickel zinc ferrite catalysts in
             the degradation of 4-chlorophenol from water under neutral conditions. J Water Process
             Eng 2015;8:e37–49.
         [22] Chaturvedi S, Dave PN, Shah N. Applications of nano-catalyst in new era. J Saudi Chem
             Soc 2012;16(3):307–25.
                       ¸
         [23] Babursah S, Cakmakci M, Kinaci C. Analysis and monitoring: costing textile effluent
             recovery and reuse. Filtr Separat 2006;43(5):26–30.
         [24] Rashidi HR, Sulaiman NMN, Hashim NA, Hassan CRC, Ramli MR. Synthetic reactive
             dye wastewater treatment by using nano-membrane filtration. Desalin Water Treat
             2015;55(1):86–95.
         [25] Sharma V, Sharma A. Nanotechnology: an emerging future trend in wastewater treatment
             with its innovative products and processes. Nanotechnology 2012;1(2).
         [26] Ho HL, Chan WK, Blondy A, Yeung KL, Schrotter J-C. Experiment and modeling of
             advanced ozone membrane reactor for treatment of organic endocrine disrupting pollu-
             tants in water. Catal Today 2012;193(1):120–7.
         [27] Zhang F, Ge Z, Grimaud J, Hurst J, He Z. Long-term performance of liter-scale microbial
             fuel cells treating primary effluent installed in a municipal wastewater treatment facility.
             Environ Sci Technol 2013;47(9):4941–8.
         [28] Jang JH, Lee J, Jung S-Y, Choi D-C, Won Y-J, Ahn KH, et al. Correlation between particle
             deposition and the size ratio of particles to patterns in nano-and micro-patterned mem-
             brane filtration systems. Sep Purif Technol 2015;156:608–16.
         [29] Guo J, Zhang Q, Cai Z, Zhao K. Preparation and dye filtration property of electrospun
             polyhydroxybutyrate–calcium alginate/carbon nanotubes composite nanofibrous filtration
             membrane. Sep Purif Technol 2016;161:69–79.
         [30] Qu X, Brame J, Li Q, Alvarez PJ. Nanotechnology for a safe and sustainable water
             supply: enabling integrated water treatment and reuse. Acc Chem Res 2012;46
             (3):834–43.
         [31] Ma H, Wang H, Na C. Microwave-assisted optimization of platinum-nickel nanoalloys for
             catalytic water treatment. Appl Catal B Environ 2015;163:198–204.
         [32] Akhavan O, Ghaderi E. Photocatalytic reduction of graphene oxide nanosheets on TiO 2
             thin film for photoinactivation of bacteria in solar light irradiation. J Phys Chem C
             2009;113(47):20214–20.
         [33] Lin S-T, Thirumavalavan M, Jiang T-Y, Lee J-F. Synthesis of ZnO/Zn nano photocatalyst
             using modified polysaccharides for photodegradation of dyes. Carbohydr Polym
             2014;105:1–9.
         [34] Anjum M, Al-Makishah NH, Barakat M. Wastewater sludge stabilization using pre-
             treatment methods. Process Saf Environ Prot 2016;102:615–32.
         [35] Wold A. Photocatalytic properties of TiO 2 . Chem Mater 1993;5(3):280–3.
         [36] Mondal K, Kumar J, Sharma A. Photocatalytic macroporous carbon films by spin coating;
             2013.
         [37] Wu C-H. Comparison of azo dye degradation efficiency using UV/single semiconductor
             and UV/coupled semiconductor systems. Chemosphere 2004;57(7):601–8.