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1.  FUNDAMENTALS, NEW APPROACHES, AND REVIEWS

2.  GENERAL CHARACTERISATION TECHNIQUES AND MODELLING

3.  CRYSTALLINE SILICON—BULK CELLS AND TECHNOLOGY

  • 22
    Granek F, Hermle M, Huljic D, et al. Enhanced lateral current transport via the front N+ diffused layer of n-type high-efficiency back-junction back-contact silicon solar cells. Progress in Photovoltaics: Research and Applications 2009; 17(1): 4756.
  • 23
    Gatz S, Plagwitz H, Altermatt PP, et al. Thermal stability of amorphous silicon/silicon nitride stacks for passivating crystalline silicon solar cells. Applied Physics Letters 2008; 93(17): 173502.
  • 24
    Lim B, Hermann S, Bothe K, et al. Solar cells on low-resistivity boron-doped Czochralski-grown silicon with stabilized efficiencies of 20%. Applied Physics Letters 2008; 93(16): 162102.
  • 25
    Chung HY, Chen CH, Chu HS. Analysis of Pyramidal Surface Texturization of Silicon Solar Cells by Molecular Dynamics Simulations. International Journal of Photoenergy 2008; 282791.
  • 26
    Gundel P, Schubert MC, Warta W. Origin of trapping in multicrystalline silicon. Journal of Applied Physics 2008; 104(7): 073716.
  • 27
    Arenas MC, Hu HL, del Rio JA, et al. Photovoltage and J-V features of porous silicon. Revista Mexicana De Fisica 2008; 54(5): 391396.
  • 28
    Lee J, Lakshminarayan N, Dhungel SK, et al. Optimization of fabrication process of high-efficiency and low-cost crystalline silicon solar cell for industrial applications. Solar Energy Materials and Solar Cells 2009; 93(2): 256261.

4.  THIN FILM SILICON, AMORPHOUS AND MICRO/NANO-CRYSTALLINE SILICON, HETEROJUNCTION CELLS

  • 29
    Kunz O, Wong J, Janssens J, et al. Shunting problems due to sub-micron pinholes in evaporated solid-phase crystallised poly-Si thin-film solar cells on glass. Progress in Photovoltaics: Research and Applications 2009; 17(1): 3546.
  • 30
    Sai H, Fujiwara H, Kondo M, et al. Enhancement of light trapping in thin-film hydrogenated microcrystalline Si solar cells using back reflectors with self-ordered dimple pattern. Applied Physics Letters 2008; 93(14): 143501.
  • 31
    Hiza S, Yamada A, Konagai M. Characterization of Defects-Location in Hydrogenated Microcrystalline Silicon Thin Films and Its Influence on Solar Cell Performance. Japanese Journal of Applied Physics 2008; 47(8): 62226227.
  • 32
    Hossain SM, Anopchenko A, Prezioso S, et al. Subband gap photoresponse of nanocrystalline silicon in a metal-oxide-semiconductor device. Journal of Applied Physics 2008; 104(7): 074917.
  • 33
    Kuzma-Filipek IJ, Duerinckx F, Van Kerschaver E, et al. Chirped porous silicon reflectors for thin-film epitaxial silicon solar cells. Journal of Applied Physics 2008; 104(7): 073529.
  • 34
    Woerdenweber J, Merdzhanova T, Schmitz R, et al. Influence of base pressure and atmospheric contaminants on a-Si:H solar cell properties. Journal of Applied Physics 2008; 104(9): 094507.

5.  ORGANIC AND HYBRID CELLS

  • 35
    Wang L, Xu M, Ying L, et al. [70] Fullerend-based Efficient Bulk Heterojuction Solar Cells. Acta Polymerica Sinica 2008; 10: 993997.
  • 36
    Ma CQ, Fonrodona M, Schikora MC, et al. Solution-Processed Bulk-Heterojunction Solar Cells Based on Monodisperse Dendritic Oligothiophenes. Advanced Functional Materials 2008; 18(20): 33233331.
  • 37
    Zhihua X, Bin H. Photovoltaic processes of singlet and triplet excited states in organic solar cells. Advanced Functional Materials 2008; 18(17): 26112617.
  • 38
    Mitzi DB, Yuan M, Liu W, et al. A High-Efficiency Solution-Deposited Thin-Film Photovoltaic Device. Advanced Materials 2008; 20(19): 3657.
  • 39
    Deibel C, Baumann A, Dyakonov V. Polaron recombination in pristine and annealed bulk heterojunction solar cells. Applied Physics Letters 2008; 93(16): 163303.
  • 40
    Gupta D, Bag M, Narayan KS. Area dependent efficiency of organic solar cells. Applied Physics Letters 2008; 93(16): 163301.
  • 41
    Arranz-Andres J, Blau WJ. Enhanced device performance using different carbon nanotube types in polymer photovoltaic devices. Carbon 2008; 46(15): 20672075.
  • 42
    Lu JP, Liang FS, Drolet N, et al. Crystalline low band-gap alternating indolocarbazole and benzothiadiazole-cored oligothiophene copolymer for organic solar cell applications. Chemical Communications 2008; 42: 53155317.
  • 43
    Bisquert J, Garcia-Belmonte G, Munar A, et al. Band unpinning and photovoltaic model for P3HT:PCBM organic bulk heterojunctions under illumination. Chemical Physics Letters 2008; 465(1–3): 5762.
  • 44
    Schulz GL, Holdcroft S. Conjugated Polymers Bearing Iridium Complexes for Triplet Photovoltaic Devices. Chemistry of Materials 2008; 20(16): 53515355.
  • 45
    Williams SS, Hampton MJ, Gowrishankar V, et al. Nanostructured Titania-Polymer Photovoltaic Devices Made Using PFPE-Based Nanomolding Techniques. Chemistry of Materials 2008; 20(16): 52295234.
  • 46
    Kalita G, Adhikari S, Aryal HR, et al. Functionalization of multi-walled carbon nanotubes (MWCNTs) with nitrogen plasma for photovoltaic device application. Current Applied Physics 2009; 9(2): 346351.
  • 47
    Fernando J, Senadeera GKR. Synthesis and characterization of carboxylated thiophene co-polymers and their use in photovoltaic cells. Current Science 2008; 95(6): 743750.
  • 48
    Tsung-Syun H, Chun-Yuan H, Yan-Kuin S, et al. High-efficiency polymer photovoltaic devices with glycerol-modified buffer layer. IEEE Photonics Technology Letters 2008; 20(23): 19351937.
  • 49
    Kabra D, Verma J, Vidhyadhiraja NS, et al. Model for Studies of Lateral Photovoltaic Effect in Polymeric Semiconductors. Ieee Sensors Journal 2008; 8(9–10): 16631671.
  • 50
    Ashassi-Sorkhabi H, Asghari E, Mirmohsen A. Photovoltaic Properties of Polyaniline-copoly(butyl acrylate/vinyl acetate) Composite. Iranian Polymer Journal 2008; 17(9): 711719.
  • 51
    Curran S, Talla J, Dias S, et al. Microconcentrator photovoltaic cell (the m-C cell): Modeling the optimum method of capturing light in an organic fiber based photovoltaic cell. Journal of Applied Physics 2008; 104(6): 064305.
  • 52
    Haldi A, Sharma A, Potscavage WJ, et al. Equivalent circuit model for organic single-layer diodes. Journal of Applied Physics 2008; 104(6): 064503.
  • 53
    Jun G, Jin H, Yanbing H, et al. Planar polymer photovoltaic cells with millimeter interelectrode spacing. Journal of Applied Physics 2008; 104(8): 084512.
  • 54
    Hau SK, Yip HL, Acton O, et al. Interfacial modification to improve inverted polymer solar cells. Journal of Materials Chemistry 2008; 18(42): 51135119.
  • 55
    Zhang FL, Bijleveld J, Perzon E, et al. High photovoltage achieved in low band gap polymer solar cells by adjusting energy levels of a polymer with the LUMOs of fullerene derivatives. Journal of Materials Chemistry 2008; 18(45): 54685474.
  • 56
    Ferenczi TAM, Nelson J, Belton C, et al. Planar heterojunction organic photovoltaic diodes via a novel stamp transfer process. Journal of Physics: Condensed Matter 2008; 20(47): 475203.
  • 57
    Huang WY, Huang PT, Han YK, et al. Aggregation and Gelation Effects on the Performance of Poly(3-hexylthiophene)/Fullerene Solar Cells. Macromolecules 2008; 41(20): 74857489: 10.1021/ma801368z.
  • 58
    Huang Zhong Y, Jun Biao P. Performance and lifetime improvement of polymer/fullerene blend photovoltaic cells with a C60 interlayer. Organic Electronics 2008; 9(6): 10221025.
  • 59
    Jin H, Hou Y, Teng F, et al. Effect of molecular aggregation by thermal treatment on photovoltaic properties of MEH-PPV: Fullerene-based solar cells. Solar Energy Materials and Solar Cells 2009; 93(2): 289294.
  • 60
    Solanki A, Gupta A, Iyer SSK, et al. Photovoltaic effect in arylenevinylene-co-pyrrolenevinylene (AVPV). Solar Energy Materials and Solar Cells 2009; 93(2): 211214.
  • 61
    Chen L-C, Wang C-C, Cheng C-B. Influence of dopant and polymeric matrix on Indium tin oxide/p-zinc phtalocyanine/n-Si hybrid solar cells. Thin Solid Films 2009; 517(5): 17901793.

6.  PHOTOELECTROCHEMICAL CELLS

  • 62
    Skupien K, Putyra P, Walter J, et al. Catalytic materials manufactured by the polyol process for monolithic dye-sensitized solar cells. Progress in Photovoltaics: Research and Applications 2009; 17(1): 6773.
  • 63
    Chia-Yuan C, Jian-Ging C, Shi-Jhang W, et al. Multifunctionalized ruthenium-based supersensitizers for highly efficient dye-sensitized solar cells. Angewandte Chemie International Edition 2008; 47(38): 73427345.
  • 64
    Hyunbong C, Sanghoon K, Sang Ook K, et al. Stepwise cosensitization of nanocrystalline TiO2 films utilizing Al2O3 layers in dye-sensitized solar cells. Angewandte Chemie International Edition 2008; 47(43): 82598263.
  • 65
    Sakaguchi S, Pandey SS, Okada K, et al. Probing TiO2/Dye Interface in Dye Sensitized Solar Cells Using Surface Potential Measurement. Applied Physics Express 2008; 1(10): 105001.
  • 66
    Lin CJ, Yu WY, Chien SH. Rough conical-shaped TiO2-nanotube arrays for flexible backilluminated dye-sensitized solar cells. Applied Physics Letters 2008; 93(13): 133107.
  • 67
    Abbotto A, Barolo C, Bellotto L, et al. Electron-rich heteroaromatic conjugated bipyridine based ruthenium sensitizer for efficient dye-sensitized solar cells. Chemical Communications 2008; 42: 53185320.
  • 68
    Kim S, Kim D, Choi H, et al. Enhanced photovoltaic performance and long-term stability of quasi-solid-state dye-sensitized solar cells via molecular engineering. Chemical Communications 2008; 40: 49514953.
  • 69
    Liu WH, Wu IC, Lai CH, et al. Simple organic molecules bearing a 3,4-ethylenedioxythiophene linker for efficient dye-sensitized solar cells. Chemical Communications 2008; 41: 51525154.
  • 70
    Wu XH, Wang S, Guo Y, et al. Enhanced Energy Conversion Efficiency of La3+-Modified Nanoporous TiO2 Electrode Sensitized with a Ruthenium Complex. Chinese Journal of Chemistry 2008; 26(10): 19391943.
  • 71
    Xiong B-T, Zhou B-X, Bai J, et al. Light scattering of nanocrystalline TiO2 film used in dye-sensitized solar cells. Chinese Physics B 2008; 17(10): 37133719.
  • 72
    Liu Y, Shen H, Chen W, et al. Novel photoelectrochromic cells fabricated with wirelike photo-electrode. Chinese Science Bulletin 2008; 53(20): 31733177.
  • 73
    Byoung-Kuk L, Jang-Joo K. Enhanced efficiency of dye-sensitized solar cells by UV-O3 treatment of TiO2 layer. Current Applied Physics 2009; 9(2): 404408.
  • 74
    Jong Hyeok P, Byung-Woo K, Jun Hyuk M. Dual functions of clay nanoparticles with high aspect ratio in dye-sensitized solar cells. Electrochemical and Solid-State Letters 2008; 11(10): B 171173.
  • 75
    Wonjoo L, Woo-Chul K, Sun Ki M, et al. Spectral broadening in quantum dots-sensitized photoelectrochemical solar cells based on CdSe and Mg-doped CdSe nanocrystals. Electrochemistry Communications 2008; 10(11): 16991702.
  • 76
    Korfiatis DP, Potamianou SF, Thoma KAT. Modeling of dye-sensitized titanium dioxide solar cells. Ionics 2008; 14(6): 545548.
  • 77
    Maity S, Haldar A, Manik NB. Effect of plasticizer on safranine-T-dye-based solid-state photo electrochemical cell. Ionics 2008; 14(6): 549554.
  • 78
    Son KM, Kang MG, Vittal R, et al. Effects of substituents of imidazolium cations on the performance of dye-sensitized TiO2 solar cells. Journal of Applied Electrochemistry 2008; 38(12): 16471652.
  • 79
    Fuke N, Fukui A, Islam A, et al. Electron transport in back contact dye-sensitized solar cells. Journal of Applied Physics 2008; 104(6): 064307.
  • 80
    Kim JJ, Choi H, Lee JW, et al. A polymer gel electrolyte to achieve >=6% power conversion efficiency with a novel organic dye incorporating a low-band-gap chromophore. Journal of Materials Chemistry 2008; 18(43): 52235229.
  • 81
    Chi B, Zhao L, Li J, et al. TiO2 Mesoporous Thick Films with Large-Pore Structure for Dye-Sensitized Solar Cell. Journal of Nanoscience and Nanotechnology 2008; 8(8): 38773882.
  • 82
    Cheng HM, Chiu WH, Lee CH, et al. Formation of Branched ZnO Nanowires from Solvothermal Method and Dye-Sensitized Solar Cells Applications. Journal of Physical Chemistry C 2008; 112(42): 1635916364.
  • 83
    Park JK, Lee HR, Chen JP, et al. Photoelectrochemical Properties of Doubly beta-Functionalized Porphyrin Sensitizers for Dye-Sensitized Nanocrystalline-TiO2 Solar Cells. Journal of Physical Chemistry C 2008; 112(42): 1669116699.
  • 84
    Shi D, Pootrakulchote N, Li RZ, et al. New Efficiency Records for Stable Dye-Sensitized Solar Cells with Low-Volatility and Ionic Liquid Electrolytes. Journal of Physical Chemistry C 2008; 112(44): 1704617050.
  • 85
    Kun-Mu L, Suryanarayanan V, Kuo-Chuan H. A photo-physical and electrochemical impedance spectroscopy study on the quasi-solid state dye-sensitized solar cells based on poly(vinylidene fluoride-co-hexafluoropropylene). Journal of Power Sources 2008; 185(2): 16051612.
  • 86
    Karim A, Cho YR, Park JS, et al. Comparison of Three Different Click Reaction Methods for the Synthesis of Fluorene-Based Polymers and Performance in Quasi-Solid-State DSSCs. Macromolecular Chemistry and Physics 2008; 209(19): 19681975.
  • 87
    McCormick C. Eutectic Melts Improve Stability of Electrolytes Used in Dye-Sensitized Solar Cells. MRS Bulletin 2008; 33(10): 899899.
  • 88
    Guo L, Pan X, Dai SY. Electrolytes in Dye-Sensitized Solar Cells. Progress in Chemistry 2008; 20(10): 15951605.
  • 89
    Kim D, Kang MS, Song K, et al. Molecular engineering of organic sensitizers containing indole moiety for dye-sensitized solar cells. Tetrahedron 2008; 64(45): 1041710424.

7.  CIS, CIGS, CdTe AND II-VI CELLS

  • 90
    Naghavi N, Hubert C, Etcheberry A, et al. Compositional engineering of chemical bath deposited (Zn,Cd)S buffer layers for electrodeposited CuIn(S,Se)2 and coevaporated Cu(In,Ga)Se2 solar cells. Progress in Photovoltaics: Research and Applications 2009; 17(1): 19.
  • 91
    Mitzi DB, Yuan M, Liu W, et al. A High-Efficiency Solution-Deposited Thin-Film Photovoltaic Device. Advanced Materials 2008; 20(19): 36573662.
  • 92
    Min Sik K, Larina L, Jae Ho Y, et al. Fabrication of CdTe solar cell using an Inx (OOH,S)y/CdS double layer as a heterojunction counterpart. Current Applied Physics 2009; 9(2): 455459.
  • 93
    Lee W, Kang SH, Min SK, et al. Co-sensitization of vertically aligned TiO2 nanotubes with two different sizes of CdSe quantum dots for broad spectrum. Electrochemistry Communications 2008; 10(10): 15791582.
  • 94
    Nerat M, Cernivec G, Smole F, et al. Simulation study of the effects of grain shape and size on the performance of Cu(In,Ga)Se2 solar cells. Journal of Applied Physics 2008; 104(8): 083706.
  • 95
    Borah MN, Chaliha S, Sarmah PC, et al. Studies on current-voltage characteristics of ITO/(n)CdSe-Al heterojunctions. Journal of Optoelectronics and Advanced Materials 2008; 10(10): 27932799.
  • 96
    Shih-Min C, Min-Hsiung H, Ing-Chi L, et al. Al-doped ZnO/Cu2 O heterojunction fabricated on (200) and (111)-orientated Cu2O substrates. Journal of the Electrochemical Society 2008; 155(11): H 923928.
  • 97
    Ahn BT, Larina L, Kim KH, et al. Development of new buffer layers for Cu(In,Ga)Se2 solar cells. Pure and Applied Chemistry 2008; 80(10): 20912102.
  • 98
    Ochoa-Landín R, Vigil-Galan O, Vorobiev YV, et al. Chemically-deposited Te layers improving the parameters of back contacts for CdTe solar cells. Solar Energy 2009; 83(1): 134138.

8.  III-V, QUANTUM WELL, SPACE, CONCENTRATOR AND THERMOPHOTOVOLTAIC CELLS

  • 99
    Canovas E, Marti A, Luque A, et al. Optimum nitride concentration in multiband III-N-V alloys for high efficiency ideal solar cells. Applied Physics Letters 2008; 93(17): 174109.
  • 100
    Neufeld CJ, Toledo NG, Cruz SC, et al. High quantum efficiency InGaN/GaN solar cells with 2.95 eV band gap. Applied Physics Letters 2008; 93(14): 143502.
  • 101
    Fukushige S, Akahoshi Y, Watanabe K, et al. Solar-array arcing due to plasma created by space-debris impact. IEEE Transactions on Plasma Science 2008; 36(5): 24342439.
  • 102
    Galofaro JT, Vayner BV, Hillard GB, et al. SSTE-4 program advanced photovoltaic cell technologies: ground chamber test results. IEEE Transactions on Plasma Science 2008; 36(5): 24252433.
  • 103
    Masui H, Toyoda K, Mengu C. Electrostatic discharge plasma propagation speed on solar panel in simulated geosynchronous environment. IEEE Transactions on Plasma Science 2008; 36(5): 23872394.
  • 104
    Mateo-Velez JC, Inguimbert V, Roussel JF, et al. ESDs on solar cells-degradation, modeling, and importance of the test setup. IEEE Transactions on Plasma Science 2008; 36(5): 23952403.
  • 105
    Lai LW, Chen JT, Lou LR, et al. Performance Improvement of (NH4)2Sx -Treated III-V Compounds Multijunction Solar Cell Using Surface Treatment. Journal of the Electrochemical Society 2008; 155(12): B1270B1273.
  • 106
    Zhao HJ, Yiyong W, Xiao JD, et al. A study on the electric properties of single-junction GaAs solar cells under the combined radiation of low-energy protons and electrons. Nuclear Instruments & Methods in Physics Research Section 2008; 266(18): 40554057.
  • 107
    Yang MD, Liu YK, Shen JL, et al. Improvement of conversion efficiency for multi-junction solar cells by incorporation of Au nanoclusters. Optics Express 2008; 16(20): 1575415758.
  • 108
    Liu GP, Xuan YM, Han Y, et al. Investigation of one-dimensional Si/SiO2 hotonic crystals for thermophotovoltaic filter. Science in China Series E 2008; 51(11): 20312039.
  • 109
    Lal NN, Blakers AW. Sliver cells in thermophotovoltaic systems. Solar Energy Materials and Solar Cells 2009; 93(2): 167175.

9.  TERRESTRIAL MODULES, BOS COMPONENTS, BUILDING INTEGRATED, SYSTEMS AND APPLICATIONS

  • 110
    Osterwald CR, McMahon TJ. History of accelerated and qualification testing of terrestrial photovoltaic modules: A literature review. Progress in Photovoltaics: Research and Applications 2009; 17(1): 1133.
  • 111
    Barnett A, Kirkpatrick D, Honsberg C, et al. Short Communication: Accelerated Publication Very high efficiency solar cell modules. Progress in Photovoltaics: Research and Applications 2009; 17(1): 7583.
  • 112
    Koeppel G, Korpas M. Improving the network infeed accuracy of non-dispatchable generators with energy storage devices. Electric Power Systems Research 2008; 78(12): 20242036.
  • 113
    Iioka D, Sakakibara K, Yokomizu Y, et al. Distribution voltage rise at dense photovoltaic generation area and its suppression by SVC. Electrical Engineering in Japan 2009; 166(2): 4753.
  • 114
    Ipsakis D, Voutetakis S, Seferlis P, et al. The effect of the hysteresis band on power management strategies in a stand-alone power system. Energy 2008; 33(10): 15371550.
  • 115
    Pavinatto E, Peres M, Reis P, et al. Small power generation. IEEE Industry Applications Magazine 2008; 14(6): 6268.
  • 116
    Jung-Min K, Bong-Hwan K, Kwang-Hee N. Three-phase photovoltaic system with three-level boosting MPPT control. IEEE Transactions on Power Electronics 2008; 23(5): 23192327.
  • 117
    Kimball JW, Krein PT. Discrete-time ripple correlation control for maximum power point tracking. IEEE Transactions on Power Electronics 2008; 23(5): 23532362.
  • 118
    Yang C, Smedley K. Three-phase boost-type grid-connected inverter. IEEE Transactions on Power Electronics 2008; 23(5): 23012309.
  • 119
    Zerhouni FZ, Zegrar M, Benmessaoud MT, et al. A novel method to optimize photovoltaic generator operation. International Journal of Energy Research 2008; 32(15): 14441453.
  • 120
    Garcia-Valverde R, Miguel C, Martinez-Bejar R, et al. Optimized photovoltaic generator-water electrolyser coupling through a controlled DC-DC converter. International Journal of Hydrogen Energy 2008; 33(20): 53525362.
  • 121
    Gibson TL, Kelly NA. Optimization of solar powered hydrogen production using photovoltaic electrolysis devices. International Journal of Hydrogen Energy 2008; 33(21): 59315940.
  • 122
    Tributsch H. Photovoltaic hydrogen generation. International Journal of Hydrogen Energy 2008; 33(21): 59115930.
  • 123
    Joshi AS, Tiwari A, Tiwari GN, et al. Performance evaluation of a hybrid photovoltaic thermal (PV/T) (glass-to-glass) system. International Journal of Thermal Sciences 2009; 48(1): 154164.
  • 124
    Min BD, Lee JP, Kim JH, et al. A Novel Grid-Connected PV PCS with New High Efficiency Converter. Journal of Power Electronics 2008; 8(4): 309316.
  • 125
    Onar OC, Uzunoglu M, Alam MS. Modeling, control and simulation of an autonomous wind turbine/photovoltaic/fuel cell/ultra-capacitor hybrid power system. Journal of Power Sources 2008; 185(2): 12731283.
  • 126
    Fan ZY, Javey A. Solar cells on curtains. Nature Materials 2008; 7(11): 835836.
  • 127
    Mellit A, Kalogirou SA, Hontoria L, et al. Artificial intelligence techniques for sizing photovoltaic systems: A review. Renewable and Sustainable Energy Reviews 2009; 13(2): 406419.
  • 128
    Almonacid F, Rus C, Hontoria L, et al. Characterisation of Si-crystalline PV modules by artificial neural networks. Renewable Energy 2009; 34(4): 941949.
  • 129
    Kaldellis JK, Spyropoulos GC, Kavadias KA, et al. Experimental validation of autonomous PV-based water pumping system optimum sizing. Renewable Energy 2009; 34(4): 11061113.
  • 130
    Sungur C. Multi-axes sun-tracking system with PLC control for photovoltaic panels in Turkey. Renewable Energy 2009; 34(4): 11191125.
  • 131
    Yun GY, Steemers K. Implications of urban settings for the design of photovoltaic and conventional façades. Solar Energy 2009; 83(1): 6980.
  • 132
    Chow T-T, Qiu Z, Li C. Potential application of “see-through” solar cells in ventilated glazing in Hong Kong. Solar Energy Materials and Solar Cells 2009; 93(2): 230238.
  • 133
    Iencinella D, Centurioni E, Grazia Busana M. Thin-film solar cells on commercial ceramic tiles. Solar Energy Materials and Solar Cells 2009; 93(2): 206210.

10.  POLICY, ECONOMICS, EDUCATION, HEALTH, ENVIRONMENT AND THE SOLAR RESOURCE

  • 134
    Ju-Young K, Gyu-Yeob J, Won-Hwa H. The performance and economical analysis of grid-connected photovoltaic systems in Daegu, Korea. Applied Energy 2009; 86(2): 265272.
  • 135
    Frondel M, Ritter N, Schmidt CM. Germany's solar cell promotion: dark clouds on the horizon. Energy Policy 2008; 36(11): 41984204.
  • 136
    Kassenga GR. The Status and Constraints of Solar Photovoltaic Energy Development in Tanzania. Energy Sources Part B 2008; 3(4): 420432.
  • 137
    Peidong Z, Yanli Y, jin S, et al. Opportunities and challenges for renewable energy policy in China. Renewable and Sustainable Energy Reviews 2009; 13(2): 439449.
  • 138
    Dalton GJ, Lockington DA, Baldock TE. Feasibility analysis of renewable energy supply options for a grid-connected large hotel. Renewable Energy 2009; 34(4): 955964.
  • 139
    Taleb HM, Pitts AC. The potential to exploit use of building-integrated photovoltaics in countries of the Gulf Cooperation Council. Renewable Energy 2009; 34(4): 10921099.

11.  NEW MATERIALS

  • 140
    Ichimura M, Takagi H. Electrodeposited ZnO/SnS Heterostructures for Solar Cell Application. Japanese Journal of Applied Physics 2008; 47(10): 78457847.
  • 141
    Gordillo G, Botero M, Oyola JS. Synthesis and study of optical and structural properties of thin films based on new photovoltaic materials. Microelectronics Journal 2008; 39(11): 13511353.
  • 142
    Lim KS, Shevaleevskiy O. Nanocrystalline silicon carbide films for solar photovoltaics: The role of dangling-bond defects. Pure and Applied Chemistry 2008; 80(10): 21412150.
  • 143
    Terasawa S, Inoue T, Ihara M. Fabrication of [beta]-FeSi2/Si composite films for photovoltaic applications by using scanning annealing. Solar Energy Materials and Solar Cells 2009; 93(2): 215221.