Environmental Engineering Reference
In-Depth Information
90. Yodyingyong S, Zhou XY, Zhang QF, Triampo D, Xi JT, Park K, Limketkai B, Cao GZ
(2010) Enhanced photovoltaic performance of nanostructured hybrid solar cell using highly
oriented TiO2 nanotubes. J Phys Chem C 114(49):21851-21855. doi:
10.1021/Jp1077888
91. Ravirajan P, Peiro AM, Nazeeruddin MK, Graetzel M, Bradley DDC, Durrant JR, Nelson J
(2006) Hybrid polymer/zinc oxide photovoltaic devices with vertically oriented ZnO
nanorods and an amphiphilic molecular interface layer. J Phys Chem B 110(15):7635-7639.
doi:
10.1021/Jp0571372
92. Peiro AM, Ravirajan P, Govender K, Boyle DS, O'Brien P, Bradley DDC, Nelson J, Durrant
JR (2006) Hybrid polymer/metal oxide solar cells based on ZnO columnar structures.
J Mater Chem 16(21):2088-2096. doi:
10.1039/B602084d
93. Olson DC, Lee YJ, White MS, Kopidakis N, Shaheen SE, Ginley DS, Voigt JA, Hsu JWP
(2007) Effect of polymer processing on the performance of poly(3-hexylthiophene)/ZnO
nanorod
photovoltaic
devices.
J
Phys
Chem
C
111(44):16640-16645.
doi:
10.1021/
94. Lee YJ, Lloyd MT, Olson DC, Grubbs RK, Lu P, Davis RJ, Voigt JA, Hsu JWP (2009)
Optimization of ZnO nanorod array morphology for hybrid photovoltaic devices. J Phys
Chem C 113(35):15778-15782. doi:
10.1021/Jp904387z
95. Olson DC, Piris J, Collins RT, Shaheen SE, Ginley DS (2006) Hybrid photovoltaic devices
of polymer and ZnO nanofiber composites. Thin Solid Films 496(1):26-29. doi:
10.1016/
96. Greene LE, Law M, Yuhas BD, Yang PD (2007) ZnO-TiO2 core-shell nanorod/P3HT solar
cells. J Phys Chem C 111(50):18451-18456. doi:
10.1021/Jp077593l
97. Hao YZ, Pei J, Wei Y, Cao YH, Jiao SH, Zhu F, Li JJ, Xu DH (2010) Efficient
semiconductor-sensitized solar cells based on poly(3-hexylthiophene)@CdSe@ZnO core-
shell nanorod arrays. J Phys Chem C 114(18):8622-8625. doi:
10.1021/Jp911263d
98. Takanezawa K, Hirota K, Wei QS, Tajima K, Hashimoto K (2007) Efficient charge
collection with ZnO nanorod array in hybrid photovoltaic devices. J Phys Chem C
111(19):7218-7223. doi:
10.1021/Jp071418n
99. Takanezawa K, Tajima K, Hashimoto K (2008) Efficiency enhancement of polymer
photovoltaic devices hybridized with ZnO nanorod arrays by the introduction of a vanadium
oxide buffer layer. Appl Phys Lett 93(6):063308. doi:
10.1063/1.2972113
100. Kuo CY, Gau C (2009) Arrangement of band structure for organic-inorganic photovoltaics
embedded with silicon nanowire arrays grown on indium tin oxide glass. Appl Phys Lett
95(5):053302-053304. doi:
10.1063/1.3189088
101. Peng KQ, Lee ST (2011) Silicon nanowires for photovoltaic solar energy conversion. Adv
Mater 23(2):198-215. doi:
10.1002/adma.201002410
102. Novotny CJ, Yu ET, Yu PKL (2008) InP nanowire/polymer hybrid photodiode. Nano Lett
8(3):775-779. doi:
10.1021/Nl072372c
103. Wang P, Zhao X, Li B (2011) ZnO-coated CuO nanowire arrays: fabrications,
optoelectronic properties, and photovoltaic applications. Opt Express 19(12):11271-11279
104. Ravirajan P, Haque SA, Durrant JR, Bradley DDC, Nelson J (2005) The effect of polymer
optoelectronic properties on the performance of multilayer hybrid polymer/TiO2 solar cells.
Adv Funct Mater 15(4):609-618. doi:
10.1002/adfm.200400165
105. Goh C, Scully SR, McGehee MD (2007) Effects of molecular interface modification in
hybrid organic-inorganic photovoltaic cells. J Appl Phys 101(11):114503. doi:
10.1063/
106. Kudo N, Honda S, Shimazaki Y, Ohkita H, Ito S, Benten H (2007) Improvement of charge
injection efficiency in organic-inorganic hybrid solar cells by chemical modification of
metal
oxides
with
organic
molecules.
Appl
Phys
Lett
90(18):183513.
doi:
107. Allen CG, Baker DJ, Albin JM, Oertli HE, Gillaspie DT, Olson DC, Furtak TE, Collins RT
(2008) Surface modification of ZnO using triethoxysilane-based molecules. Langmuir
24(23):13393-13398. doi:
10.1021/La802621n
Search WWH ::
Custom Search