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In order to help keep readers up to date in the field, each issue of Progress in Photovoltaics will contain a list of recently published journal articles most relevant to its aims and scope. This list is drawn from an extremely wide range of journals, including IEEE Transactions on Electron Devices, Journal of Applied Physics, Applied Physics Letters, Progress in Photovoltaics and Solar Energy Materials and Solar Cells. To assist the reader, the list is separated into broad categories, but please note that these classifications are by no means strict. Also note that inclusion in the list is not an endorsement of a paper's quality. If you have any suggestions, please email Santosh Shrestha at s.shrestha@unsw.edu.au.

FUNDAMENTALS, NEW APPROACHES AND REVIEWS

  1. Top of page
  2. FUNDAMENTALS, NEW APPROACHES AND REVIEWS
  3. GENERAL CHARACTERISATION TECHNIQUES AND MODELLING
  4. CRYSTALLINE SILICON—BULK CELLS AND TECHNOLOGY
  5. THIN FILM, AMORPHOUS AND MICRO/NANO-CRYSTALLINE SILICON, HETEROJUNCTION CELLS
  6. ORGANIC AND HYBRID CELLS
  7. PHOTOELECTROCHEMICAL CELLS
  8. CIS, CIGS, CdTe AND II–VI CELLS
  9. III–V, QUANTUM WELL, SPACE, CONCENTRATOR AND THERMOPHOTOVOLTAIC CELLS
  10. TERRESTRIAL MODULES, BOS COMPONENTS, BUILDING INTEGRATED, SYSTEMS AND APPLICATIONS
  11. POLICY, ECONOMICS, EDUCATION, HEALTH, ENVIRONMENT AND THE SOLAR RESOURCE

Dimmock JAR, Day S, Kauer M, et al. Demonstration of a hot-carrier photovoltaic cell, Progress in Photovoltaics: Research and Applications 2013; 22(2): 151160.

Dou LT, You JB, Hong ZR, et al. 25th Anniversary article: a decade of organic/polymeric photovoltaic research. Advanced Materials 2013; 25(46): 66426671.

Docampo P, Ball JM, Darwich M, et al. Efficient organometal trihalide perovskite planar-heterojunction solar cells on flexible polymer substrates. Nature Communications 2013; 4: (10.1038/ncomms3761).

GENERAL CHARACTERISATION TECHNIQUES AND MODELLING

  1. Top of page
  2. FUNDAMENTALS, NEW APPROACHES AND REVIEWS
  3. GENERAL CHARACTERISATION TECHNIQUES AND MODELLING
  4. CRYSTALLINE SILICON—BULK CELLS AND TECHNOLOGY
  5. THIN FILM, AMORPHOUS AND MICRO/NANO-CRYSTALLINE SILICON, HETEROJUNCTION CELLS
  6. ORGANIC AND HYBRID CELLS
  7. PHOTOELECTROCHEMICAL CELLS
  8. CIS, CIGS, CdTe AND II–VI CELLS
  9. III–V, QUANTUM WELL, SPACE, CONCENTRATOR AND THERMOPHOTOVOLTAIC CELLS
  10. TERRESTRIAL MODULES, BOS COMPONENTS, BUILDING INTEGRATED, SYSTEMS AND APPLICATIONS
  11. POLICY, ECONOMICS, EDUCATION, HEALTH, ENVIRONMENT AND THE SOLAR RESOURCE

Walter D, Rosenits P, Berger B, et al. Determination of the minority carrier lifetime in crystalline silicon thin-film material, Progress in Photovoltaics: Research and Applications 2013; 22(2): 180188.

Zhang X, Sun XH, Jiang LD. Absorption enhancement using nanoneedle array for solar cell. Applied Physics Letters 2013; 103(21): 10.1063/1.4832216.

Khan F, Baek SH, Park Y, et al. Extraction of diode parameters of silicon solar cells under high illumination conditions. Energy Conversion and Management 2013; 76: 421429.

Abdelhamid M, Singh R, Omar M. Review of microcrack detection techniques for silicon solar cells. IEEE Journal of Photovoltaics 2014; 4(1): 514524.

Fellmeth T, Clement F, Biro D. Analytical modeling of industrial-related silicon solar cells. IEEE Journal of Photovoltaics 2014; 4(1): 504513.

Giaffreda D, Magnone P, Meneghini M, et al. Local shunting in multicrystalline silicon solar cells: distributed electrical simulations and experiments. IEEE Journal of Photovoltaics 2014; 4(1): 4047.

Gjessing J, Marstein ES. An optical model for predicting the quantum efficiency of solar modules. IEEE Journal of Photovoltaics 2014; 4(1): 304310.

Leite MS, Abashin M, Lezec HJ, et al. Mapping the local photoelectronic properties of polycrystalline solar cells through high resolution laser-beam-induced current microscopy. IEEE Journal of Photovoltaics 2014; 4(1): 311316.

White TP, Lal NN, Catchpole KR. Tandem solar cells based on high-efficiency c-Si bottom cells: top cell requirements for 30% efficiency. IEEE Journal of Photovoltaics 2014; 4(1): 208214.

Wan FC, Tang FL, Zhu ZX, et al. First-principles investigation of the optical properties of CuIn (SxSe1-x)(2). Materials Science in Semiconductor Processing 2013; 16(6): 14221427.

Bermel P. Photon management modeling and beyond for photovoltaics. Optics Communications 2014; 314: 6670.

Herrero R, Dominguez C, Askins S, et al. Luminescence inverse method For CPV optical characterization. Optics Express 2013; 21(22): A1028-A1034.

Hertel K, Hupkes J, Pflaum C. An image processing approach to approximating interface textures of microcrystalline silicon layers grown on existing aluminum-doped zinc oxide textures. Optics Express 2013; 21(22): A977-A990.

Appelbaum J, Peled A. Parameters extraction of solar cells – a comparative examination of three methods. Solar Energy Materials and Solar Cells 2014; 122(0): 164173.

CRYSTALLINE SILICON—BULK CELLS AND TECHNOLOGY

  1. Top of page
  2. FUNDAMENTALS, NEW APPROACHES AND REVIEWS
  3. GENERAL CHARACTERISATION TECHNIQUES AND MODELLING
  4. CRYSTALLINE SILICON—BULK CELLS AND TECHNOLOGY
  5. THIN FILM, AMORPHOUS AND MICRO/NANO-CRYSTALLINE SILICON, HETEROJUNCTION CELLS
  6. ORGANIC AND HYBRID CELLS
  7. PHOTOELECTROCHEMICAL CELLS
  8. CIS, CIGS, CdTe AND II–VI CELLS
  9. III–V, QUANTUM WELL, SPACE, CONCENTRATOR AND THERMOPHOTOVOLTAIC CELLS
  10. TERRESTRIAL MODULES, BOS COMPONENTS, BUILDING INTEGRATED, SYSTEMS AND APPLICATIONS
  11. POLICY, ECONOMICS, EDUCATION, HEALTH, ENVIRONMENT AND THE SOLAR RESOURCE

Kim EY, Kim J. Effects of the boron-doped p(+) emitter on the efficiency of the n-type silicon solar cell. Advances in Materials Science and Engineering 2013: 10.1155/2013/974507.

Herasimenka SY, Tracy CJ, Sharma V, et al. Surface passivation of n-type c-Si wafers by a-Si/SiO2/SiNx stack with <1 cm/s effective surface recombination velocity. Applied Physics Letters 2013; 103(18): 10.1063/1.4827821.

Suxiang Z, Qi Q, Song Z, et al. Rear passivation of commercial multi-crystalline PERC solar cell by PECVD Al2O3. Applied Surface Science 2014; 290: 6670.

Boscke TS, Kania D, Schollhorn C, et al. Fully ion implanted and coactivated industrial n-type cells with 20.5% efficiency. IEEE Journal of Photovoltaics 2014; 4(1): 4851.

Hallam BJ, Hamer PG, Wenham SR, et al. Advanced bulk defect passivation for silicon solar cells. IEEE Journal of Photovoltaics 2014; 4(1): 8895.

Jian W, Yunyu L, Xusheng W, et al. Application of ion implantation emitter in PERC solar cells. IEEE Journal of Photovoltaics 2014; 4(1): 5257.

Jingbing D, Longzhong T, Yanbin Z, et al. High-efficiency full back contacted cells using industrial processes. IEEE Journal of Photovoltaics 2014; 4(1): 130133.

Yuguo T, Young-Woo O, Zimbardi F, et al. Fully ion-implanted and screen-printed 20.2% Efficient front junction silicon cells on 239 cm2 n-type CZ substrate. IEEE Journal of Photovoltaics 2014; 4(1): 5863.

Kim H, Lee Y, Shin C, et al. Two-step texture process for high-efficiency crystalline silicon solar cell applications. Journal of Nanoscience and Nanotechnology 2013; 13(12): 79167919.

Basu PK, Cunnusamy J, Sarangi D, et al. Novel selective emitter process using non-acidic etch-back for inline-diffused silicon wafer solar cells. Renewable Energy 2014; 66(0): 6977.

Ali K, Khan SA, Mat Jafri MZ. Enhancement of silicon solar cell efficiency by using back surface field in comparison of different antireflective coatings. Solar Energy 2014; 101(0): 17.

Choi Y, Kim D-k, Do EC, et al. Interdigitated front contact crystalline silicon solar cell. Solar Energy 2014; 100(0): 94101.

Moreno M, Murias D, Martínez J, et al. A comparative study of wet and dry texturing processes of c-Si wafers for the fabrication of solar cells. Solar Energy 2014; 101(0): 182191.

Wang X-Y, Wang J-L, Wang H. Improvement of the efficiency and power output of solar cells using nanoparticles and annealing. Solar Energy 2014; 101(0): 100104.

Bivour M, Schröer S, Hermle M, et al. Silicon heterojunction rear emitter solar cells: less restrictions on the optoelectrical properties of front side TCOs. Solar Energy Materials and Solar Cells 2014; 122(0): 120129.

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

  1. Top of page
  2. FUNDAMENTALS, NEW APPROACHES AND REVIEWS
  3. GENERAL CHARACTERISATION TECHNIQUES AND MODELLING
  4. CRYSTALLINE SILICON—BULK CELLS AND TECHNOLOGY
  5. THIN FILM, AMORPHOUS AND MICRO/NANO-CRYSTALLINE SILICON, HETEROJUNCTION CELLS
  6. ORGANIC AND HYBRID CELLS
  7. PHOTOELECTROCHEMICAL CELLS
  8. CIS, CIGS, CdTe AND II–VI CELLS
  9. III–V, QUANTUM WELL, SPACE, CONCENTRATOR AND THERMOPHOTOVOLTAIC CELLS
  10. TERRESTRIAL MODULES, BOS COMPONENTS, BUILDING INTEGRATED, SYSTEMS AND APPLICATIONS
  11. POLICY, ECONOMICS, EDUCATION, HEALTH, ENVIRONMENT AND THE SOLAR RESOURCE

Zimmermann T, Flikweert Aj, Merdzhanova T, et al. Deposition of intrinsic hydrogenated amorphous silicon for thin-film solar cells – a comparative study for layers grown statically by RF-PECVD and dynamically by VHF-PECVD, Progress in Photovoltaics: Research and Applications 2013; 22(2): 198207.

Dore J, Ong D, Varlamov S, et al. Progress in laser-crystallized thin-film polycrystalline silicon solar cells: intermediate layers, light trapping, and metallization. IEEE Journal of Photovoltaics 2014; 4(1): 3339.

Nagamatsu KA, Avasthi S, Jhaveri J, et al. A 12% efficient silicon/PEDOT:PSS heterojunction solar cell fabricated at 100C. IEEE Journal of Photovoltaics 2014; 4(1): 260264.

Taguchi M, Yano A, Tohoda S, et al. 24.7% Record efficiency HIT solar cell on thin silicon wafer. IEEE Journal of Photovoltaics 2014; 4(1): 9699.

Lee YJ, Yeon CB, Yun SJ, et al. High roughness Ag back reflector on a metal underlayer for thin film solar cell applications. Materials Research Bulletin 2013; 48(12): 50935098.

Da Y, Xuan YM. Role of surface recombination in affecting the efficiency of nanostructured thin-film solar cells. Optics Express 2013; 21(22): A1065A1077.

Bivour M, Schröer S, Hermle M, et al. Silicon heterojunction rear emitter solar cells: less restrictions on the optoelectrical properties of front side TCOs. Solar Energy Materials and Solar Cells 2014; 122(0): 120129.

Huang Y, Sahraei N, Widenborg PI, et al. Enhanced light trapping in polycrystalline silicon thin-film solar cells using plasma-etched submicron textures. Solar Energy Materials and Solar Cells 2014; 122(0): 146151.

Qiu Y, Kunz O, Fejfar A, et al. On the effects of hydrogenation of thin film polycrystalline silicon: a key factor to improve heterojunction solar cells. Solar Energy Materials and Solar Cells 2014; 122(0): 3139.

ORGANIC AND HYBRID CELLS

  1. Top of page
  2. FUNDAMENTALS, NEW APPROACHES AND REVIEWS
  3. GENERAL CHARACTERISATION TECHNIQUES AND MODELLING
  4. CRYSTALLINE SILICON—BULK CELLS AND TECHNOLOGY
  5. THIN FILM, AMORPHOUS AND MICRO/NANO-CRYSTALLINE SILICON, HETEROJUNCTION CELLS
  6. ORGANIC AND HYBRID CELLS
  7. PHOTOELECTROCHEMICAL CELLS
  8. CIS, CIGS, CdTe AND II–VI CELLS
  9. III–V, QUANTUM WELL, SPACE, CONCENTRATOR AND THERMOPHOTOVOLTAIC CELLS
  10. TERRESTRIAL MODULES, BOS COMPONENTS, BUILDING INTEGRATED, SYSTEMS AND APPLICATIONS
  11. POLICY, ECONOMICS, EDUCATION, HEALTH, ENVIRONMENT AND THE SOLAR RESOURCE

Small CE, Tsang SW, Chen S, et al. Loss mechanisms in thick-film low-bandgap polymer solar cells. Advanced Energy Materials 2013; 3(7): 909916.

You JB, Chen CC, Hong ZR, et al. 10.2% Power conversion efficiency polymer tandem solar cells consisting of two identical sub-cells. Advanced Materials 2013; 25(29): 39733978.

Zhang MJ, Gu Y, Guo X, et al. Efficient polymer solar cells based on benzothiadiazole and alkylphenyl substituted benzodithiophene with a power conversion efficiency over 8%. Advanced Materials 2013; 25(35): 49444949.

Bilby D, Amonoo J, Sykes ME, et al. Reduction of open circuit voltage loss in a polymer photovoltaic cell via interfacial molecular design: insertion of a molecular spacer. Applied Physics Letters 2013; 103(20): 10.1063/1.4831974.

Thambidurai M, Kim JY, Song J, et al. High performance inverted organic solar cells with solution processed Ga-doped ZnO as an interfacial electron transport layer. Journal of Materials Chemistry C 2013; 1(48): 81618166.

Rodovsky DB, Peet J, Shao N, et al. Quantifying the relationship between the maximum achievable voltage and current levels in low-bandgap polymer photovoltaics. Journal of Physical Chemistry C 2013; 117(49): 2595525960.

Borges I, Aquino AJA, Kohn A, et al. Ab initio modeling of excitonic and charge-transfer states in organic semiconductors: the PTB1/PCBM Low band gap system. Journal of the American Chemical Society 2013; 135(49): 1825218255.

Betancur R, Romero-Gomez P, Martinez-Otero A, et al. Transparent polymer solar cells employing a layered light-trapping architecture. Nature Photonics 2013; 7(12): 9951000.

Hormann U, Kraus J, Gruber M, et al. Quantification of energy losses in organic solar cells from temperature-dependent device characteristics. Physical Review B 2013; 88(23): 10.1103/PhysRevB.88.235307.

Omar A, Abdullah H. Electron transport analysis in zinc oxide-based dye-sensitized solar cells: a review. Renewable and Sustainable Energy Reviews 2014; 31(0): 149157.

Zuo L, Yao J, Li H, et al. Assessing the origin of the S-shaped I–V curve in organic solar cells: an improved equivalent circuit model. Solar Energy Materials and Solar Cells 2014; 122(0): 8893.

PHOTOELECTROCHEMICAL CELLS

  1. Top of page
  2. FUNDAMENTALS, NEW APPROACHES AND REVIEWS
  3. GENERAL CHARACTERISATION TECHNIQUES AND MODELLING
  4. CRYSTALLINE SILICON—BULK CELLS AND TECHNOLOGY
  5. THIN FILM, AMORPHOUS AND MICRO/NANO-CRYSTALLINE SILICON, HETEROJUNCTION CELLS
  6. ORGANIC AND HYBRID CELLS
  7. PHOTOELECTROCHEMICAL CELLS
  8. CIS, CIGS, CdTe AND II–VI CELLS
  9. III–V, QUANTUM WELL, SPACE, CONCENTRATOR AND THERMOPHOTOVOLTAIC CELLS
  10. TERRESTRIAL MODULES, BOS COMPONENTS, BUILDING INTEGRATED, SYSTEMS AND APPLICATIONS
  11. POLICY, ECONOMICS, EDUCATION, HEALTH, ENVIRONMENT AND THE SOLAR RESOURCE

Shi YT, Wang K, Du Y, et al. Solid-state synthesis of ZnO nanostructures for quasi-solid dye-sensitized solar cells with high efficiencies up to 6.46%. Advanced Materials 2013; 25(32): 44134419.

Chou CC, Hu FC, Yeh HH, et al. Highly efficient dye-sensitized solar cells based on panchromatic ruthenium sensitizers with quinolinylbipyridine anchors. Angewandte Chemie 2014; 53(1): 178183.

Hung WI, Liao YY, Hsu CY, et al. High-performance dye-sensitized solar cells based on phenothiazine dyes containing double anchors and thiophene spacers. Chemistry-an Asian Journal 2014; 9(1): 357366.

Jeon N, Kim DW. Dye-sensitized solar cells assembled with composite gel polymer electrolytes containing nanosized Al2O3 particles. Journal of Nanoscience and Nanotechnology 2013; 13(12): 79557958.

Sun KC, Yun SH, Yoon CH, et al. Enhanced power conversion efficiency of dye-sensitized solar cells using nanoparticle/nanotube double layered film. Journal of Nanoscience and Nanotechnology 2013; 13(12): 79387943.

Latini A, Cavallo C, Aldibaja FK, et al. Efficiency improvement of DSSC photoanode by scandium doping of mesoporous titania beads. Journal of Physical Chemistry C 2013; 117(48): 2527625289.

Chen KF, Liu CH, Hsieh CK, et al. New fabrication process of long-life dye-sensitized solar cells by in situ gelation of quasi-solid polymer electrolytes. Journal of Power Sources 2014; 247: 939946.

Qinghua L, Qunwei T, Lin L, et al. A simple approach of enhancing photovoltaic performances of quasi-solid-state dye-sensitized solar cells by integrating conducting polyaniline into electrical insulating gel electrolyte. Journal of Power Sources 2014; 245: 468474.

Shalabi AS, El Mahdy AM, Assem MM, et al. Theoretical characterisation of highly efficient dye-sensitised solar cells. Molecular Physics 2014; 112(1): 2234.

CIS, CIGS, CdTe AND II–VI CELLS

  1. Top of page
  2. FUNDAMENTALS, NEW APPROACHES AND REVIEWS
  3. GENERAL CHARACTERISATION TECHNIQUES AND MODELLING
  4. CRYSTALLINE SILICON—BULK CELLS AND TECHNOLOGY
  5. THIN FILM, AMORPHOUS AND MICRO/NANO-CRYSTALLINE SILICON, HETEROJUNCTION CELLS
  6. ORGANIC AND HYBRID CELLS
  7. PHOTOELECTROCHEMICAL CELLS
  8. CIS, CIGS, CdTe AND II–VI CELLS
  9. III–V, QUANTUM WELL, SPACE, CONCENTRATOR AND THERMOPHOTOVOLTAIC CELLS
  10. TERRESTRIAL MODULES, BOS COMPONENTS, BUILDING INTEGRATED, SYSTEMS AND APPLICATIONS
  11. POLICY, ECONOMICS, EDUCATION, HEALTH, ENVIRONMENT AND THE SOLAR RESOURCE

Chantana J, Watanabe T, Teraji S, et al. Relationship between open-circuit voltage in Cu(In,Ga)Se-2 solar cell and peak position of (220/204) preferred orientation near its absorber surface. Applied Physics Letters 2013; 103(22): 10.1063/1.4832995.

Bing H, Shiyou C, Hui-Xiong D, et al. Origin of reduced efficiency in Cu(In,Ga)Se2 solar cells with high Ga concentration: alloy solubility versus intrinsic defects. IEEE Journal of Photovoltaics 2014; 4(1): 477482.

Pianezzi F, Reinhard P, Chirila A, et al. Defect formation in Cu(In,Ga)Se-2 thin films due to the presence of potassium during growth by low temperature co-evaporation process. Journal of Applied Physics 2013; 114(19): 10.1063/1.4832781.

Xiao ZY, Li YF, Yao B, et al. Bandgap engineering of Cu2CdxZn1-xSnS4 alloy for photovoltaic applications: a complementary experimental and first-principles study. Journal of Applied Physics 2013; 114(18): 10.1063/1.4829457.

Su ZH, Sun KW, Han ZL, et al. Fabrication of Cu2ZnSnS4 solar cells with 5.1% efficiency via thermal decomposition and reaction using a non-toxic sol–gel route. Journal of Materials Chemistry A 2014; 2(2): 500509.

Chen C, Li FM, Li GQ, et al. Double-sided transparent electrodes of TiO2 nanotube arrays for highly efficient CdS quantum dot-sensitized photoelectrodes. Journal of Materials Science 2014; 49(4): 18681874.

Laemmle A, Wuerz R, Powalla M. Efficiency enhancement of Cu(In,Ga)Se-2 thin-film solar cells by a post-deposition treatment with potassium fluoride. Physica Status Solidi-Rapid Research Letters 2013; 7(9): 631634.

III–V, QUANTUM WELL, SPACE, CONCENTRATOR AND THERMOPHOTOVOLTAIC CELLS

  1. Top of page
  2. FUNDAMENTALS, NEW APPROACHES AND REVIEWS
  3. GENERAL CHARACTERISATION TECHNIQUES AND MODELLING
  4. CRYSTALLINE SILICON—BULK CELLS AND TECHNOLOGY
  5. THIN FILM, AMORPHOUS AND MICRO/NANO-CRYSTALLINE SILICON, HETEROJUNCTION CELLS
  6. ORGANIC AND HYBRID CELLS
  7. PHOTOELECTROCHEMICAL CELLS
  8. CIS, CIGS, CdTe AND II–VI CELLS
  9. III–V, QUANTUM WELL, SPACE, CONCENTRATOR AND THERMOPHOTOVOLTAIC CELLS
  10. TERRESTRIAL MODULES, BOS COMPONENTS, BUILDING INTEGRATED, SYSTEMS AND APPLICATIONS
  11. POLICY, ECONOMICS, EDUCATION, HEALTH, ENVIRONMENT AND THE SOLAR RESOURCE

Bennett MF, Bittner ZS, Forbes DV, et al. Epitaxial lift-off of quantum dot enhanced GaAs single junction solar cells. Applied Physics Letters 2013; 103(21): 10.1063/1.4833776.

Farrell RM, Al-Heji AA, Neufeld CJ, et al. Effect of intentional p-GaN surface roughening on the performance of InGaN/GaN solar cells. Applied Physics Letters 2013; 103(24): 10.1063/1.4844955.

Shanmugam M, Jain N, Jacobs-Gedrim R, et al. Layered insulator hexagonal boron nitride for surface passivation in quantum dot solar cell. Applied Physics Letters 2013; 103(24): 10.1063/1.4848235.

France RM, Garcia I, McMahon WE, et al. Lattice-mismatched 0.7-eV GaInAs solar cells grown on GaAs using GaInP compositionally graded buffers. IEEE Journal of Photovoltaics 2014; 4(1): 190195.

Fujii H, Toprasertpong K, Watanabe K, et al. Evaluation of carrier collection efficiency in multiple quantum well solar cells. IEEE Journal of Photovoltaics 2014; 4(1): 237243.

Chang JY, Yen SH, Chang YA, et al. Numerical investigation of high-efficiency InGaN-based multijunction solar cell. IEEE Transactions on Electron Devices 2013; 60(12): 41404145.

Lee YJ, Yao YC, Tsai MT, et al. Current matching using CdSe quantum dots to enhance the power conversion efficiency of InGaP/GaAs/Ge tandem solar cells. Optics Express 2013; 21(22): A953A963.

Wu MH, Chang SP, Liao WY, et al. Efficiency of GaN/InGaN double-heterojunction photovoltaic cells under concentrated illumination. Surface & Coatings Technology 2013; 231: 253256.

Tülek R, Arslan E, Bayrakl&#55349;&#56996; A, et al. The effect of GaN thickness inserted between two AlN layers on the transport properties of a lattice matched AlInN/AlN/GaN/AlN/GaN double channel heterostructure. Thin Solid Films 2014; 551(0): 146152.

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

  1. Top of page
  2. FUNDAMENTALS, NEW APPROACHES AND REVIEWS
  3. GENERAL CHARACTERISATION TECHNIQUES AND MODELLING
  4. CRYSTALLINE SILICON—BULK CELLS AND TECHNOLOGY
  5. THIN FILM, AMORPHOUS AND MICRO/NANO-CRYSTALLINE SILICON, HETEROJUNCTION CELLS
  6. ORGANIC AND HYBRID CELLS
  7. PHOTOELECTROCHEMICAL CELLS
  8. CIS, CIGS, CdTe AND II–VI CELLS
  9. III–V, QUANTUM WELL, SPACE, CONCENTRATOR AND THERMOPHOTOVOLTAIC CELLS
  10. TERRESTRIAL MODULES, BOS COMPONENTS, BUILDING INTEGRATED, SYSTEMS AND APPLICATIONS
  11. POLICY, ECONOMICS, EDUCATION, HEALTH, ENVIRONMENT AND THE SOLAR RESOURCE

Kenny RP, Chatzipanagi AI, Sample T. Preconditioning of thin-film PV module technologies for calibration. Progress in Photovoltaics: Research and Applications 2013; 22(2): 166172.

Virtuani A, Fanni L. Seasonal power fluctuations of amorphous silicon thin-film solar modules: distinguishing between different contributions. Progress in Photovoltaics: Research and Applications 2013; 22(2): 208217.

Qasem H, Betts TR, Müllejans H, et al. Dust-induced shading on photovoltaic modules. Progress in Photovoltaics: Research and Applications 2013; 22(2): 218226.

Bernardon DP, Mello APC, Pfitscher LL, et al. Real-time reconfiguration of distribution network with distributed generation. Electric Power Systems Research 2014; 107: 5967.

Rodrigo P, Fernandez EF, Almonacid F, et al. Outdoor measurement of high concentration photovoltaic receivers operating with partial shading on the primary optics. Energy 2013; 61: 583588.

Tajuddin MFN, Ayob SM, Salam Z, et al. Evolutionary based maximum power point tracking technique using differential evolution algorithm. Energy and Buildings 2013; 67: 245252.

Bauer A, Hanisch J, Ahlswede E. An effective single solar cell equivalent circuit model for two or more solar cells connected in series. IEEE Journal of Photovoltaics 2014; 4(1): 340347.

Braun S, Nissler R, Ebert C, et al. High efficiency multi-busbar solar cells and modules. IEEE Journal of Photovoltaics 2014; 4(1): 148153.

Agamy MS, Harfman-Todorovic M, Elasser A, et al. An efficient partial power processing DC/DC converter for distributed PV architectures. IEEE Transactions on Power Electronics 2014; 29(2): 674686.

Khanna R, Zhang QH, Stanchina WE, et al. Maximum power point tracking using model reference adaptive control. IEEE Transactions on Power Electronics 2014; 29(3): 14901499.

Batzelis EI, Routsolias IA, Papathanassiou SA. An explicit PV string model based on the Lambert W function and simplified MPP expressions for operation under partial shading. IEEE Transactions on Sustainable Energy 2014; 5(1): 301312.

Bonfiglio A, Brignone M, Delfino F, et al. Optimal control and operation of grid-connected photovoltaic production units for voltage support in medium-voltage networks. IEEE Transactions on Sustainable Energy 2014; 5(1): 254263.

Lee J, Park C, Dao VA, et al. Direct metallization local Al-back surface field for high efficiency screen printed crystalline silicon solar cells. Journal of Nanoscience and Nanotechnology 2013; 13(11): 75517555.

Tsai HL. Complete PV model considering its thermal dynamics. Journal of the Chinese Institute of Engineers 2013; 36(8): 10731082.

Chine W, Mellit A, Pavan AM, et al. Fault detection method for grid-connected photovoltaic plants. Renewable Energy 2014; 66(0): 99110.

Li Y, Su Y, Shu L. An ARMAX model for forecasting the power output of a grid connected photovoltaic system. Renewable Energy 2014; 66(0): 7889.

Qi J, Zhang Y, Chen Y. Modeling and maximum power point tracking (MPPT) method for PV array under partial shade conditions. Renewable Energy 2014; 66(0): 337345.

Chekired F, Mellit A, Kalogirou SA, et al. Intelligent maximum power point trackers for photovoltaic applications using FPGA chip: a comparative study. Solar Energy 2014; 101(0): 8399.

Lorente DG, Pedrazzi S, Zini G, et al. Mismatch losses in PV power plants. Solar Energy 2014; 100(0): 4249.

Ma T, Yang H, Lu L. Development of a model to simulate the performance characteristics of crystalline silicon photovoltaic modules/strings/arrays. Solar Energy 2014; 100(0): 3141.

Solórzano J, Egido MA. Hot-spot mitigation in PV arrays with distributed MPPT (DMPPT). Solar Energy 2014; 101(0): 131137.

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

  1. Top of page
  2. FUNDAMENTALS, NEW APPROACHES AND REVIEWS
  3. GENERAL CHARACTERISATION TECHNIQUES AND MODELLING
  4. CRYSTALLINE SILICON—BULK CELLS AND TECHNOLOGY
  5. THIN FILM, AMORPHOUS AND MICRO/NANO-CRYSTALLINE SILICON, HETEROJUNCTION CELLS
  6. ORGANIC AND HYBRID CELLS
  7. PHOTOELECTROCHEMICAL CELLS
  8. CIS, CIGS, CdTe AND II–VI CELLS
  9. III–V, QUANTUM WELL, SPACE, CONCENTRATOR AND THERMOPHOTOVOLTAIC CELLS
  10. TERRESTRIAL MODULES, BOS COMPONENTS, BUILDING INTEGRATED, SYSTEMS AND APPLICATIONS
  11. POLICY, ECONOMICS, EDUCATION, HEALTH, ENVIRONMENT AND THE SOLAR RESOURCE

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