Photovoltaics literature survey (no. 152)

At a Glance

Metadata	Details
Publication Date	2019-07-22
Journal	Progress in Photovoltaics Research and Applications
Authors	Ziv Hameiri
Institutions	UNSW Sydney

Abstract

Wang, J, Chen, HY, Wei, SH, et al. Materials design of solar cell absorbers beyond perovskites and conventional semiconductors via combining tetrahedral and octahedral coordination. Advanced Materials 2019; 31( 17): 1806593. Kost, C, Palzer, A, Sterchele, P, et al. Coal phase out, energy efficiency, and electricity imports: key elements to realize the energy transformation. Applied Physics Reviews 2019; 6( 1): 011308. Halme, J, Makinen, P. Theoretical efficiency limits of ideal coloured opaque photovoltaics. Energy and Environmental Science 2019; 12( 4): 1274- 1285. Zhang, LC, Lv, MY, Zhu, WY, et al. Mission-based multidisciplinary optimization of solar-powered hybrid airship. Energy Conversion and Management 2019; 185: 44- 54. Behura, SK, Wang, C, Wen, Y, et al. Graphene-semiconductor heterojunction sheds light on emerging photovoltaics. Nature Photonics 2019; 13( 5): 312- 318. Tanaka, T, Hayashi, T, Nagayama, T, et al. Proposal of novel degradation diagnosis method for photovoltaic module employing xenon flash lighting system and detector capacitor. Energy Conversion and Management 2019; 186: 450. Ananthanarayanan, D, Wong, J, Er-Chien, W, et al. Determination of metal-induced recombination of n-type bifacial Si solar cells using special print patterns. IEEE Journal of Photovoltaics 2019; 9( 3): 643. Fung, TH, Khan, MU, Zhang, Y, et al. Improved ray tracing on random pyramid texture via application of Phong scattering. IEEE Journal of Photovoltaics 2019; 9( 3): 591. Hyeondeuk, Y, Minemoto, T, Takahashi, T. Photovoltage decay measurements by photo-assisted Kelvin probe force microscopy on Cu (In,Ga)Se2 solar cells. IEEE Journal of Photovoltaics 2019; 9( 2): 483. Stromer, D, Vetter, A, Oezkan, HC, et al. Enhanced crack segmentation (eCS): a reference algorithm for segmenting cracks in multicrystalline silicon solar cells. IEEE Journal of Photovoltaics 2019; 9( 3): 752. Kratzer, M, Dimitriev, OP, Fedoryak, AN, et al. The role of the probe tip material in distinguishing p- and n-type domains in bulk heterojunction solar cells by atomic force microscopy based methods. Journal of Applied Physics 2019; 125( 18): 185305. Najafi, E, Jafari, A. Ultrafast imaging of surface-exclusive carrier dynamics in silicon. Journal of Applied Physics 2019; 125( 18): 185303. Bercegol, A, Ory, D, Suchet, D, et al. Quantitative optical assessment of photonic and electronic properties in halide perovskite. Nature Communications 2019; 10: 1586. Gong, XW, Huang, Z, Sabatini, R, et al. Contactless measurements of photocarrier transport properties in perovskite single crystals. Nature Communications 2019; 10: 1591. Ali, H, Koul, S, Gregory, G, et al. In situ transmission electron microscopy study of molybdenum oxide contacts for silicon solar cells. Physica Status Solidi A-Applications and Materials Science 2019; 216( 7): 1800998. Karl, A, Osvet, A, Vetter, A, et al. Discriminating bulk versus interface shunts in organic solar cells by advanced imaging techniques. Progress in Photovoltaics: Research and Applications 2019; 27( 5): 460. Deitsch, S, Christlein, V, Berger, S, et al. Automatic classification of defective photovoltaic module cells in electroluminescence images. Solar Energy 2019; 185: 455- 468. Quan, L, Xie, K, Liu, Y, et al. Camera enhanced compressive light beam induced current sensing for efficient defect detection in photovoltaic cells. Solar Energy 2019; 183: 212- 217. Yeow, T, Jing, S, Zheng, Y, et al. Evaluation of impedance spectroscopy as a tool to characterize degradation mechanisms in silicon photovoltaics. Solar Energy 2019; 184: 52- 58. Hossain, MJ, Schneller, EJ, Li, M, et al. Incorporation of spatially-resolved current density measurements with photoluminescence for advanced parameter imaging of solar cells. Solar Energy Materials and Solar Cells 2019; 199: 136- 143. Turek, M, Sporleder, K, Luka, T. Spectral characterization of solar cells and modules using LED-based solar simulators. Solar Energy Materials and Solar Cells 2019; 194: 142- 147. Zafirovska, I, Juhl, MK, Ciesla, A, et al. Low temperature sensitivity of implied voltages from luminescence measured on crystalline silicon solar cells. Solar Energy Materials and Solar Cells 2019; 199: 50- 58. Ji, WB, Zhao, YB, Fahad, HM, et al. Dip coating passivation of crystalline silicon by Lewis acids. Acs Nano 2019; 13( 3): 3723. Xu, QW, Meng, LJ, Wang, XH. Reducing shadowing losses in silicon solar cells using cellulose nanocrystal: polymer hybrid diffusers. Applied Optics 2019; 58( 10): 2505. Yan, X, Chen, N, Bin Suhaimi, F, et al. Design, fabrication, and analysis of double-layer antireflection coatings (ARC) for industrial bifacial n-type crystalline silicon solar cells. Applied Optics 2019; 58( 15): E1- E6. Jiang, S, Jia, R, Tao, K, et al. Different methods for removing boron-rich layer and their impacts on the efficiency of interdigitated back contact solar cells. Applied Physics A-Materials Science and Processing 2019; 125( 4): 264. Mao, X, Yu, XG, Yuan, S, et al. Recombination activity of sub-grain boundaries and dislocation arrays in quasi-single crystalline silicon. Applied Physics Express 2019; 12( 5): 051012. Nunomura, S, Sakata, I, Matsubara, K. In-situ detection of interface defects in a-Si:H/c-Si heterojunction during plasma processing. Applied Physics Express 2019; 12( 5): 051006. Li, SH, Pomaska, M, Hoss, J, et al. Poly-Si/SiOx/c-Si passivating contact with 738 mV implied open circuit voltage fabricated by hot-wire chemical vapor deposition. Applied Physics Letters 2019; 114( 15): 153901. Nguyen, CT, Ohdaira, K, Matsumura, H. Control of solution wettability on fine-textured crystalline silicon surface to obtain high-quality passivation for solar cells. Applied Physics Letters 2019; 114( 13): 133901. Fan, PX, Sun, ZM, Wilkes, GC, et al. Low-temperature laser generated ultrathin aluminum oxide layers for effective c-Si surface passivation. Applied Surface Science 2019; 480: 35. Blakers, A. Development of the PERC solar cell. IEEE Journal of Photovoltaics 2019; 9( 3): 629. Chatterji, N, Antony, A, Nair, PR. Temperature coefficient of silicon-based carrier selective solar cells. IEEE Journal of Photovoltaics 2019; 9( 3): 583. Sheng, J, Wang, W, Ye, QH, et al. MACE texture optimization for mass production of high-efficiency multi-crystalline cell and module. IEEE Journal of Photovoltaics 2019; 9( 3): 918. Soohyun, B, Jae-Wook, C, Chanseok, K, et al. Effective contact formation method on high-sheet-resistance boron-doped emitter with current injection. IEEE Journal of Photovoltaics 2019; 9( 3): 615. Varshney, U, Abbott, M, Ciesla, A, et al. Evaluating the impact of SiNx thickness on lifetime degradation in silicon. IEEE Journal of Photovoltaics 2019; 9( 3): 601. Kinoshita, K, Kojima, T, Onishi, K, et al. Effect of oxygen precipitation through annealing process on lifetime degradation by Czochralski-Si crystal growth conditions. Japanese Journal of Applied Physics 2019; 58( SB): SBBF02. Lozac’h, M, Nunomura, S, Umishio, H, et al. Roles of hydrogen atoms in p-type Poly-Si/SiOx passivation layer for crystalline silicon solar cell applications. Japanese Journal of Applied Physics 2019; 58( 5): 050915. Takata, K, Fujise, J, Bonggyun, K, et al. Influence of impurities on mechanical strength of silicon crystal. Japanese Journal of Applied Physics 2019; 58( 4): 045507. Hwang, JM. Plasma charge injection technology and its application to c-Si solar cells for field-effect passivation. Journal of Applied Physics 2019; 125( 17): 173301. Vaqueiro-Contreras, M, Markevich, VP, Coutinho, J, et al. Identification of the mechanism responsible for the boron oxygen light induced degradation in silicon photovoltaic cells. Journal of Applied Physics 2019; 125( 18): 185704. Kolevatov, IL, Weiser, PM, Monakhov, EV, et al. Interaction between hydrogen and vacancy defects in crystalline silicon. Physica Status Solidi A-Applications and Materials Science 2019; 216( 10): 1800670. Morisset, A, Cabal, R, Grange, B, et al. Conductivity and surface passivation properties of boron-doped poly-silicon passivated contacts for c-Si solar cells. Physica Status Solidi A-Applications and Materials Science 2019; 216( 10): 1800603. Wu, M, Murphy, JD, Jiang, J, et al. Microstructural evolution of mechanically deformed polycrystalline silicon for Kerfless photovoltaics. Physica Status Solidi A-Applications and Materials Science 2019; 216( 10): 1800578. Unsur, V, Klein, T, Hest, M, et al. Rapid thermal processing of cost-effective contacts for silicon solar cells. Progress in Photovoltaics: Research and Applications 2019; 27( 5): 453. Kim, K, Borojevic, N, Winderbaum, S, et al. Investigation of industrial PECVD AlOx films with very low surface recombination. Solar Energy 2019; 186: 94- 105. Shetty, K, Kaushal, Y, Murthy, DS, et al. Advanced fine line double printing process for manufacturing high efficiency silicon wafer solar cells. Solar Energy 2019; 180: 301- 306. Singh, K, Nayak, M, Mudgal, S, et al. Effect of textured silicon pyramids size and chemical polishing on the performance of carrier-selective contact heterojunction solar cells. Solar Energy 2019; 183: 469- 475. Sreejith, KP, Sharma, AK, Kumbhar, S, et al. An additive-free non-metallic energy efficient industrial texturization process for diamond wire sawn multicrystalline silicon wafers. Solar Energy 2019; 184: 162- 172. Chen, J, Ge, K, Chen, B, et al. Establishment of a novel functional group passivation system for the surface engineering of c-Si solar cells. Solar Energy Materials and Solar Cells 2019; 195: 99- 105. Cruz, A, Wang, E-C, Morales-Vilches, AB, et al. Effect of front TCO on the performance of rear-junction silicon heterojunction solar cells: insights from simulations and experiments. Solar Energy Materials and Solar Cells 2019; 195: 339- 345. Derricks, C, Herguth, A, Hahn, G, et al. Industrially applicable mitigation of BO-LID in Cz-Si PERC-type solar cells within a coupled fast firing and halogen lamp based belt-line regenerator—a parameter study. Solar Energy Materials and Solar Cells 2019; 195: 358- 366. John, J, Hajjiah, A, Haslinger, M, et al. Deposition behaviour of metal impurities in acidic cleaning solutions and their impact on effective minority carrier lifetime in n-type silicon solar cells. Solar Energy Materials and Solar Cells 2019; 194: 83- 88. Li, Y, Recamán Payo, M, Singh, S, et al. Optical and electrical performance of rear side epitaxial emitters for bifacial silicon solar cell application. Solar Energy Materials and Solar Cells 2019; 195: 43- 48. Limodio, G, Yang, G, Ge, H, et al. Front and rear contact Si solar cells combining high and low thermal budget Si passivating contacts. Solar Energy Materials and Solar Cells 2019; 194: 28- 35. Lu, X, Li, Y, Lun, S, et al. High efficiency light trapping scheme used for ultrathin c-Si solar cells. Solar Energy Materials and Solar Cells 2019; 196: 57- 64. Luo, W, Chen, N, Ke, C, et al. Investigation of polysilicon passivated contact’s resilience to potential-induced degradation. Solar Energy Materials and Solar Cells 2019; 195: 168- 173. Sharma, R, Chong, AP, Li, JB, et al. Role of post-metallization anneal sequence and forming gas anneal to mitigate light and elevated temperature induced degradation of multicrystalline silicon solar cells. Solar Energy Materials and Solar Cells 2019; 195: 160- 167. Sun, C, Chen, D, Rougieux, F, et al. Kinetics and dynamics of the regeneration of boron-oxygen defects in compensated n-type silicon. Solar Energy Materials and Solar Cells 2019; 195: 174- 181. Pusch, A, Pearce, P, Ekins-Daukes, NJ. Analytical expressions for the efficiency limits of radiatively coupled tandem solar cells. IEEE Journal of Photovoltaics 2019; 9( 3): 679. Trahms, M, Jost, M, Trinh, CT, et al. All-thin-film tandem cells based on liquid phase crystallized silicon and perovskites. IEEE Journal of Photovoltaics 2019; 9( 3): 621. Hamada, K, Yonezawa, K, Yamamoto, K, et al. Vacuum deposition of CsPbI3 layers on textured Si for perovskite/Si tandem solar cells. Japanese Journal of Applied Physics 2019; 58( SB): SBBF06. Kurata, K, Ohdaira, K. Crystallization of electron beam evaporated a-Si films on textured glass substrates by flash lamp annealing. Japanese Journal of Applied Physics 2019; 58( SB): SBBF10. Thi Thuy, N, Kuroki, SI. Dependence of thin film transistor characteristics on low-angle grain boundaries of (100)-oriented polycrystalline silicon thin films. Japanese Journal of Applied Physics 2019; 58( SB): SBBJ08. Kim, CU, Yu, JC, Jung, ED, et al. Optimization of device design for low cost and high efficiency planar monolithic perovskite/silicon tandem solar cells. Nano Energy 2019; 60: 213. Rienacker, M, Warren, EL, Schnabel, M, et al. Back-contacted bottom cells with three terminals: maximizing power extraction from current-mismatched tandem cells. Progress in Photovoltaics: Research and Applications 2019; 27( 5): 410. Huanran, F, Yuan-Qiu-Qiang, Y, Xin, K, et al. New anthracene-fused nonfullerene acceptors for high-efficiency organic solar cells: energy level modulations enabling match of donor and acceptor. Advanced Energy Materials 2019; 9( 12): 1803541. Lee, T, Eom, Y, Song, CE, et al. Simple bithiophene-rhodanine-based small molecule acceptor for use in additive-free nonfullerene OPVs with low energy loss of 0.51 eV. Advanced Energy Materials 2019; 9( 16): 1804021. Lu, LL, Liao, Q, Zu, YF, et al. Significant effect of fluorination on simultaneously improving work function and transparency of anode interlayer for organic solar cells. Advanced Energy Materials 2019; 9( 15): 1803826. Luke, J, Speller, EM, Wadsworth, A, et al. Twist and degrade-impact of molecular structure on the photostability of nonfullerene acceptors and their photovoltaic blends. Advanced Energy Materials 2019; 9( 15): 1803755. Luo, ZH, Liu, T, Wang, YL, et al. Reduced energy loss enabled by a chlorinated thiophene-fused ending-group small molecular acceptor for efficient nonfullerene organic solar cells with 13.6% efficiency. Advanced Energy Materials 2019; 9( 18): 1900041. Zheng, ZL, Tummala, NR, Wang, TH, et al. Charge-transfer states at organic-organic interfaces: impact of static and dynamic disorders. Advanced Energy Materials 2019; 9( 14): 1803926. Cui, Y, Yao, HF, Hong, L, et al. Achieving over 15% efficiency in organic photovoltaic cells via copolymer design. Advanced Materials 2019; 31( 14): 1808356. Gao, K, Jo, SB, Shi, XL, et al. Over 12% efficiency nonfullerene all-small-molecule organic solar cells with sequentially evolved multilength scale morphologies. Advanced Materials 2019; 31( 12): 1807842. Sun, HL, Tang, YM, Koh, CW, et al. High-performance all-polymer solar cells enabled by an n-type polymer based on a fluorinated imide-functionalized arene. Advanced Materials 2019; 31( 15): 1807220. Wang, JQ, Zheng, Z, Zhang, DY, et al. Regulating bulk-heterojunction molecular orientations through surface free energy control of hole-transporting layers for high-performance organic solar cells. Advanced Materials 2019; 31( 17): 1806921. Yuan, J, Zhang, YQ, Zhou, LY, et al. Fused benzothiadiazole: a building block for n-type organic acceptor to achieve high-performance organic solar cells. Advanced Materials 2019; 31( 17): 1807577. Limbu, S, Pont, S, Doust, AB, et al. Impact of initial bulk-heterojunction morphology on operational stability of polymer:fullerene photovoltaic cells. Advanced Materials Interfaces 2019; 6( 6): 1801763. Chen, JY, Bi, ZZ, Xu, XB, et al. Fine optimization of morphology evolution kinetics with binary additives for efficient non-fullerene organic solar cells. Advanced Science 2019; 6( 6): 1801560. Firdaus, Y, Le Corre, VM, Khan, JI, et al. Key parameters requirements for non-fullerene-based organic solar cells with power conversion efficiency > 20%. Advanced Science 2019; 6( 9): 1802028. Tan, LC, Wang, YL, Zhang, JW, et al. Highly efficient flexible polymer solar cells with robust mechanical stability. Advanced Science 2019; 6( 7): 1801180. Zhang, CH, Heumueller, T, Leon, S, et al. A top-down strategy identifying molecular phase stabilizers to overcome microstructure instabilities in organic solar cells. Energy and Environmental Science 2019; 12( 3): 1078. Yao, HF, Cui, Y, Qian, DP, et al. 14.7% efficiency organic photovoltaic cells enabled by active materials with a large electrostatic potential difference. Journal of the American Chemical Society 2019; 141( 19): 7743. Sun, H, Chen, F, Chen, ZK. Recent progress on non-fullerene acceptors for organic photovoltaics. Materials Today 2019; 24: 94. An, QS, Wang, J, Zhang, FJ. Ternary polymer solar cells with alloyed donor achieving 14.13% efficiency and 78.4% fill factor. Nano Energy 2019; 60: 768. Lin, BJ, Zhang, L, Zhao, H, et al. Molecular packing control enables excellent performance and mechanical property of blade-cast all-polymer solar cells. Nano Energy 2019; 59: 277. Stadtmuller, B, Emmerich, S, Jungkenn, D, et al. Strong modification of the transport level alignment in organic materials after optical excitation. Nature Communications 2019; 10: 1470. Yu, ZP, Liu, ZX, Chen, FX, et al. Simple non-fused electron acceptors for efficient and stable organic solar cells. Nature Communications 2019; 10: 2152. Ullbrich, S, Benduhn, J, Jia, XK, et al. Emissive and charge-generating donor-acceptor interfaces for organic optoelectronics with low voltage losses. Nature Materials 2019; 18( 5): 459. Kweon, DH, Baek, JB. Edge-functionalized graphene nanoplatelets as metal-free electrocatalysts for dye-sensitized solar cells. Advanced Materials 2019; 31( 13): 1804440. Langmar, O, Fazio, E, Schol, P, et al. Controlling interfacial charge transfer and fill factors in CuO-based tandem dye-sensitized solar cells. Angewandte Chemie-International Edition 2019; 58( 12): 4056. Saeidi, M, Abrari, M, Ahmadi, M. Fabrication of dye-sensitized solar cell based on mixed tin and zinc oxide nanoparticles. Applied Physics a-Materials Science and Processing 2019; 125( 6): 409. Ganesh, RS, Silambarasan, K, Durgadevi, E, et al. Metal sulfide nanosheet-nitrogen-doped graphene hybrids as low-cost counter electrodes for dye-sensitized solar cells. Applied Surface Science 2019; 480: 177. Shin, SS, Suk, JH, Kang, BJ, et al. Energy-level engineering of the electron transporting layer for improving open-circuit voltage in dye and perovskite-based solar cells. Energy and Environmental Science 2019; 12( 3): 958. Baro, M, Harjwani, J, Ramaprabhu, S. Nitrogen-containing hierarchically porous tubular carbon as an efficient counter electrode for dye-sensitized solar cells. IEEE Journal of Photovoltaics 2019; 9( 3): 700. Jung-Chuan, C, Chien-Hung, K, Po-Yu, K, et al. The retardation structure for improvement of photovoltaic performances of dye-sensitized solar cell under low illumination. IEEE Journal of Photovoltaics 2019; 9( 3): 926. An, J, Yang, X, Wang, W, et al. A structurally simple donor with a low recombination rate for high-performance dye-sensitized solar cells. Solar Energy 2019; 185: 124- 130. Chen, L, Chenghao, X, X, et al. control for dye-sensitized solar cells based on polymer Solar Energy 2019; Y, Yao, J, L, et al. of to the performance of dye-sensitized solar cells. Solar Energy 2019; 183: New for in dye solar cells. Solar Energy 2019; D, L, L, et al. Fabrication of with for efficient dye-sensitized solar cells. Solar Energy 2019; U, HF, et al. and counter electrode materials for efficient dye-sensitized solar cells Solar Energy 2019; 185: SK, R, et al. Improved efficiency in dye solar cells based on Solar Energy 2019; 184: L, solar cells based on Solar Energy 2019; 184: B, N, et al. The effect of carbon on improving the performance of dye-sensitized solar cells. Solar Energy 2019; Song, X, Yang, X, Wang, H, et al. energy transfer efficiency of dye-sensitized solar cell by fine of dye Solar Energy 2019; A, M, G, et al. in dye-sensitized solar cells of surface passivation. 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Highly films by and application in perovskite solar cells. Advanced Materials 2019; 4): Xu, M, Sheng, et al. of perovskite solar cells enables high temperature and stability. Advanced Materials 2019; 16): SS, Kim, H, et al. A perovskite layer for high-efficiency solar cells. Advanced Materials 2019; 15): Yang, T, Y, et al. Achieving efficiency for perovskite solar cells. Advanced Materials 2019; 12): Zheng, D, Wang, G, Huang, W, et al. zinc oxide layers for efficient and stable perovskite solar cells. Advanced Materials 2019; 16): Tan, Tan, et al. In situ passivation and fill in perovskite solar cells. Advanced Materials 2019; 31( 14): Zhang, Wang, S, et al. the interfacial contact in perovskite solar cells. Advanced Materials Interfaces 2019; 6( 7): Kim, Yang, R, et al. flexible perovskite solar cells: Advanced Science 2019; 6( 7): Li, Jo, Hwang, et al. passivation of organic transport interlayer for perovskite solar cells. Advanced Science 2019; 6( 6): I, A, et al. Energy alignment and recombination in perovskite solar cells: on the open circuit Energy and Environmental Science 2019; 12( 4): D, I, P, et al. current in hybrid perovskite solar cells: circuit and impedance of mixed Energy and Environmental Science 2019; 12( 4): A, P, R, et al. charge transport and mixed in halide perovskites. Energy and Environmental Science 2019; 12( 4): Li, Z, et al. operational stability and processing of halide perovskite active Energy and Environmental Science 2019; 12( 4): Zheng, F, Wang, formation and its effect on electron transport in hybrid perovskites. Energy and Environmental Science 2019; 12( 4): Li, J, Chen, et al. for stable perovskite solar cells with > efficiency. Journal of the American Chemical Society 2019; 141( 15): Zhang, F, Kim, DH, Lu, et al. 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DOI: https://doi.org/10.1002/pip.3173