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Hybrid materials based on polymer nanocomposites for environmental applications 545
[25] Dayal S, Kopidakis N, Olson DC, Ginley DS, Rumbles G. Photovoltaic devices with a low
band gap polymer and CdSe nanostructures exceeding 3% efficiency. Nano Lett
2010;10:239–42.
[26] Verma D, Rao AR, Dutta V. Surfactant-free CdTe nanoparticles mixed MEH-PPV hybrid
solar cell deposited by spin coating technique. Sol Energy Mater Sol Cells 2009;
93:1482–7.
[27] Cui D, Xu J, Zhu T, Paradee G, Ashok S, Gerhold M. Harvest of near infrared light in PbSe
nanocrystal-polymer hybrid photovoltaic cells. Appl Phys Lett 2006;88:183111.
[28] Sudhagar P, Nagarajan S, Lee YG, Song D, Son T, Cho W, et al. Synergistic catalytic
effect of a composite (CoS/PEDOT:PSS) counter electrode on triiodide reduction in
dye-sensitized solar cells. ACS Appl Mater Interfaces 2011;3:1838–43.
[29] Yeh MH, Lin LY, Li YY, Chang J, Chen PW, Lee CP, et al. Composite films based on poly
(3,4-ethylene dioxythiophene):poly(styrene sulfonate) conducting polymer and TiC
nanoparticles as the counter electrodes for flexible dye-sensitized solar cells. Jpn
J Appl Phys 2012;51(10):10NE01.
[30] Liu CY, Holman ZC, Kortshagen UR. Hybrid solar cells from P3HT and silicon nano-
crystals. Nano Lett 2009;9:449–52.
[31] Kim JY, Kim M, Kim H, Joo J, Choi JH. Electrical and optical studies of organic light
emitting devices using SWCNTs-polymer nanocomposites. Opt Mater 2002;21:147–51.
[32] Alexandrou I, Kymakis E, Amaratunga GAJ. Polymer-nanotube composites: Burying nan-
otubes improves their field emission properties. Appl Phys Lett 2002;80:1435–7.
[33] Habisreutinger SN, Leijtens T, Eperon GE, Stranks SD, Nicholas RJ, Snaith HJ. Carbon
nanotube/polymer composites as a highly stable hole collection layer in perovskite solar
cells. Nano Lett 2014;14:5561–8.
[34] Ha YG, You EA, Kim BJ, Choi JH. Electrical and optical studies of organic light emitting
devices using SWCNTs-polymer nanocomposites. Opt Mater 2002;21:147–51.
[35] Wang GF, Tao XM, Wang RX. Flexible organic light-emitting diodes with a polymeric
nanocomposite anode. Nanotechnology 2008;19:145201.
[36] Fan B, Mei X, Sun K, Ouyang J. Conducting polymer/carbon nanotube composite as coun-
ter electrode of dye sensitized solar cells. Appl Phys Lett 2008;93:143103.
[37] Mills CA, Sam FLM, Alshammari AS, Rozanski LJ, Emerson NG, Silva SRP. Storage
lifetime of polymer-carbon nanotube inks for use as charge transport layers in organic light
emitting diodes. J Disp Technol 2014;10:125–31.
[38] Sun Y, Shi G. Graphene/polymer composites for energy applications. J Polym Sci
B Polym Phys 2013;51:231–53.
[39] Sun T, Guo ZD, Gu YT, Li HY, Dong GF, Shi ZJ, et al. Mobility increase in poly[2-
methoxy-5-(2’-ethylhexyloxy)-1,4-phenylenevinylene] blended with graphene. Appl
Phys Lett 2011;98:223302.
[40] Park JH, Lim YT, Park OO, Kim JK, Yu JW, Kim YC. Polymer/gold nanoparticle
nanocomposite light-emitting diodes: enhancement of electroluminescence stability and
quantum efficiency of blue-light-emitting polymers. Chem Mater 2004;16:688–92.
[41] Jheng JY, Sah PT, Chang WC, Chen JH, Chan LH. Decahedral gold nanoparticles for
enhancing performance of polymer solar cells. Dyes Pigments 2017;138:83–9.
[42] He M, Qiu F, Lin Z. Toward high-performance organic inorganic hybrid solar cells:
bringing conjugated polymers and inorganic nanocrystals in close contact. J Phys Chem
Lett 2013;4:1788–96.
[43] Ren S, Chang LY, Lim SK, Zhao J, Smith M, Zhao N, et al. Inorganic-organic hybrid
solar cell: bridging quantum dots to conjugated polymer nanowires. Nano Lett 2011;
11:3998–4002.
