Photovoltaics literature survey (No. 146)

At a Glance

Metadata	Details
Publication Date	2018-11-19
Journal	Progress in Photovoltaics Research and Applications
Authors	Ziv Hameiri

Abstract

In order to help readers stay up-to-date in the field, each issue of Progress in Photovoltaics will contain a list of recently published journal articles that are most relevant to its aims and scope. This list is drawn from an extremely wide range of journals, including IEEE Journal of Photovoltaics, Solar Energy Materials and Solar Cells, Renewable Energy, Renewable and Sustainable Energy Reviews, Journal of Applied Physics, and Applied Physics Letters. To assist readers, 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 Ziv Hameiri at [email protected]. Mahmoudi T, Yousheng W, Yoon-Bong H. Graphene and its derivatives for solar cells application. Nano Energy 2018; 47: 51-65. al Irsyad MI, Halog A, Nepal R. Renewable energy projections for climate change mitigation: an analysis of uncertainty and errors. Renewable Energy 2019; 130: 536-546. Hughes MP, Rosenthal KD, Ran NA, et al. Determining the dielectric constants of organic photovoltaic materials using impedance spectroscopy. Advanced Functional Materials 2018; 28(32): 1801542. Bedrich K, Bokalic M, Bliss M, et al. Electroluminescence imaging of PV devices: advanced vignetting calibration. IEEE Journal of Photovoltaics 2018; 8(5): 1297. Bedrich KG, Wei L, Pravettoni M, et al. Quantitative electroluminescence imaging analysis for performance estimation of PID-influenced PV modules. IEEE Journal of Photovoltaics 2018; 8(5): 1281. Ruggeri E, Van Aken BB, Isabella O, et al. Electroluminescence and dark lock-in thermography for the quality assessment of metal-wrap-through solar devices. IEEE Journal of Photovoltaics 2018; 8(5): 1174. List M, Sarkar T, Perkhun P, et al. Correct determination of charge transfer state energy from luminescence spectra in organic solar cells. Nature Communications 2018; 9: 3631. Bernardini S, Naerland TU, Coletti G, et al. Defect parameters contour mapping: a powerful tool for lifetime spectroscopy data analysis. Physica Status Solidi B-Basic Solid State Physics 2018; 255(8): 1800082. Di Y, Cuevas A, Sieu Pheng P, et al. 23% efficient p-type crystalline silicon solar cells with hole-selective passivating contacts based on physical vapor deposition of doped silicon films. Applied Physics Letters 2018; 113(6): 061603. Herguth A, Derricks C, Sperber D. A detailed study on light-induced degradation of Cz-Si PERC-type solar cells: evidence of rear surface-related degradation. IEEE Journal of Photovoltaics 2018; 8(5): 1190. Hylsky J, Strachala D, Hladisk J, et al. Design of p-type photovoltaic cells resistant to potential-induced degradation. IEEE Journal of Photovoltaics 2018; 8(5): 1215. Schube J, Tutsch L, Fellmeth T, et al. Low-resistivity screen-printed contacts on indium tin oxide layers for silicon solar cells with passivating contacts. IEEE Journal of Photovoltaics 2018; 8(5): 1208. Jensen MA, Zuschlag A, Wieghold S, et al. Evaluating root cause: the distinct roles of hydrogen and firing in activating light- and elevated temperature-induced degradation. Journal of Applied Physics 2018; 124(8): 085701. Kumar A, Melkote SN. Wear of diamond in scribing of multi-crystalline silicon. Journal of Applied Physics 2018; 124(6): 065101 Messmer C, Bivour M, Schon J, et al. Requirements for efficient hole extraction in transition metal oxide-based silicon heterojunction solar cells. Journal of Applied Physics 2018; 124(8): 085702 Zhang T, Lee CY, Wan YM, et al. Investigation of the thermal stability of MoOx as hole-selective contacts for Si solar cells. Journal of Applied Physics 2018; 124(7): 073106. Ingenito A, Nogay G, Jeangros Q, et al. A passivating contact for silicon solar cells formed during a single firing thermal annealing. Nature Energy 2018; 3(9): 800. Tsoutsouva MG, Riberi-Beridot T, Regula G, et al. In situ imaging of dislocation expansion in FZ-Si seeds during temperature ramp heating process. Physica Status Solidi A-Applications and Materials Science 2018; 215(14): 1700758. Zhang Z, Zeng Y, Jiang C-S, et al. Carrier transport through the ultrathin silicon-oxide layer in tunnel oxide passivated contact (TOPCon) c-Si solar cells. Solar Energy Materials and Solar Cells 2018; 187: 113-122. Wagner M, Wolny F, Hentsche M, et al. Correlation of the LeTID amplitude to the aluminium bulk concentration and oxygen precipitation in PERC solar cells. Solar Energy Materials and Solar Cells 2018; 187: 176-188. Vaqueiro-Contreras M, Bartlam C, Bonilla RS, et al. Graphene oxide films for field effect surface passivation of silicon for solar cells. Solar Energy Materials and Solar Cells 2018; 187: 189-193. Tong H, Liao M, Zhang Z, et al. A strong-oxidizing mixed acid derived high-quality silicon oxide tunneling layer for polysilicon passivated contact silicon solar cell. Solar Energy Materials and Solar Cells 2018; 188: 149-155. Steffens J, Fazio MA, Cavalcoli D, et al. Multi-characterization study of interface passivation quality of amorphous sub-stoichiometric silicon oxide and silicon oxynitride layers for photovoltaic applications. Solar Energy Materials and Solar Cells 2018; 187: 104-112. Sperber D, Schwarz A, Herguth A, et al. Enhanced stability of passivation quality on diffused silicon surfaces under light-induced degradation conditions. Solar Energy Materials and Solar Cells 2018; 188: 112-118. Schmidt J, Peibst R, Brendel R. Surface passivation of crystalline silicon solar cells: present and future. Solar Energy Materials and Solar Cells 2018; 187: 39-54. Rougieux FE, Sun C, Macdonald D. Determining the charge states and capture mechanisms of defects in silicon through accurate recombination analyses: A review. Solar Energy Materials and Solar Cells 2018; 187: 263-272. Rodriguez J, Wang E-C, Chen N, et al. Towards 22% efficient screen-printed bifacial n-type silicon solar cells. Solar Energy Materials and Solar Cells 2018; 187: 91-96. Panigrahi J, Vandana, Singh R, et al. Enhanced field effect passivation of c-Si surface via introduction of trap centers: Case of hafnium and aluminium oxide bilayer films deposited by thermal ALD. Solar Energy Materials and Solar Cells 2018; 188: 219-227. Paduthol A, Juhl MK, Nogay G, et al. Impact of different capping layers on carrier injection efficiency between amorphous and crystalline silicon measured using photoluminescence. Solar Energy Materials and Solar Cells 2018; 187: 55-60. Luka T, Turek M, Hagendorf C. Defect formation under high temperature dark-annealing compared to elevated temperature light soaking. Solar Energy Materials and Solar Cells 2018; 187: 194-198. Iandolo B, Davidsen RS, Hansen O. Avoiding blistering in Al2O3 deposited on planar and black Si. Solar Energy Materials and Solar Cells 2018; 187: 23-29. Haschke J, Dupré O, Boccard M, et al. Silicon heterojunction solar cells: recent technological development and practical aspects—from lab to industry. Solar Energy Materials and Solar Cells 2018; 187: 140-153. Duttagupta S, Nandakumar N, Padhamnath P, et al. monoPoly™ cells: Large-area crystalline silicon solar cells with fire-through screen printed contact to doped polysilicon surfaces. Solar Energy Materials and Solar Cells 2018; 187: 76-81. Black LE, van de Loo BWH, Macco B, et al. Explorative studies of novel silicon surface passivation materials: Considerations and lessons learned. Solar Energy Materials and Solar Cells 2018; 188: 182-189. Lim JWM, Huang S, Xu L, et al. Ultra-low reflective black silicon photovoltaics by high density inductively coupled plasmas. Solar Energy 2018; 171: 841-850. Tamang A, Sai H, Jovanov V, et al. Silicon thin-film solar cells approaching the geometric light-trapping limit: surface texture inspired by self-assembly processes. Acs Photonics 2018; 5(7): 2799-2806. Ren N, Zhu J, Shi P, et al. Controlling performance of a-Si:H solar cell with SnO2:F front electrode by introducing dual p-layers with p-a-SiOx:H/p-nc-SiOx:H nanostructure. Solar Energy 2018; 171: 907-913. Cao B, Adutwum LA, Oliynyk AO, et al. How to optimize materials and devices via design of experiments and machine learning: Demonstration using organic photovoltaics. Acs Nano 2018; 12(8): 7434-7444. Kan B, Yi YQQ, Wan XJ, et al. Ternary organic solar cells with 12.8% efficiency using two nonfullerene acceptors with complementary absorptions. Advanced Energy Materials 2018; 8(22): 1800424. Li XJ, Yao J, Angunawela I, et al. Improvement of photovoltaic performance of polymer solar cells by rational molecular optimization of organic molecule acceptors. Advanced Energy Materials 2018; 8(23): 1800815. Sahu H, Rao W, Troisi A, et al. Toward predicting efficiency of organic solar cells via machine learning and improved descriptors. Advanced Energy Materials 2018; 8(24): 1801032. Yang B, Chen Y, Cui Y, et al. Over 100-nm-thick MoOx films with superior hole collection and transport properties for organic solar cells. Advanced Energy Materials 2018; 8(25): 1800698. Zhang GC, Xia RX, Chen Z, et al. Overcoming space-charge effect for efficient thick-film non-fullerene organic solar cells. Advanced Energy Materials 2018; 8(25): 1801609. Gao W, Liu T, Ming RJ, et al. Near-infrared small molecule acceptor enabled high-performance nonfullerene polymer solar cells with over 13% efficiency. Advanced Functional Materials 2018; 28(31): 1803128. He J, Wan YM, Gao PQ, et al. Over 16.7% efficiency organic-silicon heterojunction solar cells with solution-processed dopant-free contacts for both polarities. Advanced Functional Materials 2018; 28(34): 1802192. Jin F, Yuan JY, Guo WP, et al. Improved charge generation via ultrafast effective hole-transfer in all-polymer photovoltaic blends with large highest occupied molecular orbital (HOMO) energy offset and proper crystal orientation. Advanced Functional Materials 2018; 28(31): 1801611. Cheng P, Wang JY, Zhang QQ, et al. Unique energy alignments of a ternary material system toward high-performance organic photovoltaics. Advanced Materials 2018; 30(28): 1801501. Cui Y, Zhang SQ, Liang NN, et al. Toward efficient polymer solar cells processed by a solution-processed layer-by-layer approach. Advanced Materials 2018; 30(34): 1802499. Kang Q, Yang B, Xu Y, et al. Printable MoOx anode interlayers for organic solar cells. Advanced Materials 2018; 30(35): 1801718. Xie YP, Yang F, Li YX, et al. Morphology control enables efficient ternary organic solar cells. Advanced Materials 2018; 30(38): 1803045. Zhang H, Yao HF, Hou JX, et al. Over 14% efficiency in organic solar cells enabled by chlorinated nonfullerene small-molecule acceptors. Advanced Materials 2018; 30(28): 1800613. Zhang K, Xia RX, Fan BB, et al. 11.2% all-polymer tandem solar cells with simultaneously improved efficiency and stability. Advanced Materials 2018; 30(36): 1803166. Shi ZH, Deng H, Zhao W, et al. An alternative hole extraction layer for inverted organic solar cells. Applied Physics A-Materials Science and Processing 2018; 124(10): 676. Larrain FA, Fuentes-Hernandez C, Chou WF, et al. Stable solvent for solution-based electrical doping of semiconducting polymer films and its application to organic solar cells. Energy and Environmental Science 2018; 11(8): 2216-2224. Ma XL, Gao W, Yu JS, et al. Ternary nonfullerene polymer solar cells with efficiency >13.7% by integrating the advantages of the materials and two binary cells. Energy and Environmental Science 2018; 11(8): 2134-2141. Liu X, Zhang CH, Duan CH, et al. Morphology optimization via side chain engineering enables all polymer solar cells with excellent fill factor and stability. Journal of the American Chemical Society 2018; 140(28): 8934-8943. Li ZY, Ying L, Xie RH, et al. Designing ternary blend all-polymer solar cells with an efficiency of over 10% and a fill factor of 78%. Nano Energy 2018; 51: 434-441. Tan JK, Png RQ, Zhao C, et al. Ohmic transition at contacts key to maximizing fill factor and performance of organic solar cells. Nature Communications 2018; 9: 3269. Qian DP, Zheng ZL, Yao HF, et al. Design rules for minimizing voltage losses in high-efficiency organic solar cells. Nature Materials 2018; 17(8): 703. Meng LX, Zhang YM, Wan XJ, et al. Organic and solution-processed tandem solar cells with 17.3% efficiency. Science 2018; 361(6407): 1094. Upama MB, Elumalai NK, Mahmud MA, et al. Enhanced electron transport enables over 12% efficiency by interface engineering of non-fullerene organic solar cells. Solar Energy Materials and Solar Cells 2018; 187: 273-282. Hadi A, Chen Q, Curioni M, et al. One-step fiber laser fabrication of mesoporous and compact TiO2 layers for enhanced performance of dye-sensitized solar cells. Acs Sustainable Chemistry and Engineering 2018; 6(9): 12299-12308. Nguyen HH, Gyawali G, Hoon JS, et al. Cr-doped TiO2 nanotubes with a double-layer model: an effective way to improve the efficiency of dye-sensitized solar cells. Applied Surface Science 2018; 458: 523-528. Irannejad N, Rezaei B, Ensafi AA, et al. Photovoltaic performance analysis of dye-sensitized solar cell based on the Ag complex as a light-scattering layer agent and linker molecule on TiO2 photoanode. IEEE Journal of Photovoltaics 2018; 8(5): 1230. Nemala S, Prathapani S, Kartikay P, et al. Water-based high shear exfoliated graphene-based semi-transparent stable dye-sensitized solar cells for solar power window application. IEEE Journal of Photovoltaics 2018; 8(5): 1252. Akilimali R, Selopal GS, Benetti D, et al. Hybrid TiO2-graphene nanoribbon photoanodes to improve the photoconversion efficiency of dye sensitized solar cells. Journal of Power Sources 2018; 396: 566-573. Jin K, Jin Soo K, Juwon J, et al. Electrochemically synthesized nanostructured iron carbide/carbon composite as a low-cost counter electrode for dye-sensitized solar cells. Journal of Power Sources 2018; 396: 213. Piontkowski Z, McCarnant DW. Excited-state planarization in donor-bridge dye sensitizers: Phenylene versus thiophene bridges. Journal of the American Chemical Society 2018; 140(35): 11046-11057. Yin J, Lu X. Theoretical study of electronic structure and optical properties of tin doped CuS counter electrode for dye-sensitized solar cells. Solar Energy 2018; 171: 871-875. Subalakshmi K, Senthilselvan J. Effect of fluorine-doped TiO2 photoanode on electron transport, recombination dynamics and improved DSSC efficiency. Solar Energy 2018; 171: 914-928. Chen JH, Zuo LJ, Zhang YZ, et al. High-performance thickness insensitive perovskite solar cells with enhanced moisture stability. Advanced Energy Materials 2018; 8(23): 1800438. Li M, Zhao C, Wang ZK, et al. Interface modification by ionic liquid: a promising candidate for indoor light harvesting and stability improvement of planar perovskite solar cells. Advanced Energy Materials 2018; 8(24): 1801509. Palmstrom AF, Raiford JA, Prasanna R, et al. Interfacial effects of tin oxide atomic layer deposition in metal halide perovskite photovoltaics. Advanced Energy Materials 2018; 8(23): 1800591. Tavakoli MM, Yadav P, Tavakoli R, et al. Surface engineering of TiO2 ETL for highly efficient and hysteresis-less planar perovskite solar cell (21.4%) with enhanced open-circuit voltage and stability. Advanced Energy Materials 2018; 8(23): 1800794. Wong-Stringer M, Game OS, Smith JA, et al. High-performance multilayer encapsulation for perovskite photovoltaics. Advanced Energy Materials 2018; 8(24): 1801234. Cai FL, Yan Y, Yao JX, et al. Ionic additive engineering toward high-efficiency perovskite solar cells with reduced grain boundaries and trap density. Advanced Functional Materials 2018; 28(34): 1801985. Feng JS, Zhu XJ, Yang Z, et al. Record efficiency stable flexible perovskite solar cell using effective additive assistant strategy. Advanced Materials 2018; 30(35): 1801418. Gong J, Yang MJ, Rebollar D, et al. Divalent anionic doping in perovskite solar cells for enhanced chemical stability. Advanced Materials 2018; 30(34): 1800973. Li MH, Yeh HH, Chiang YH, et al. Highly efficient 2D/3D hybrid perovskite solar cells via low-pressure vapor-assisted solution process. Advanced Materials 2018; 30(30): 1801401. Long MZ, Zhang TK, Liu MZ, et al. Abnormal synergetic effect of organic and halide ions on the stability and optoelectronic properties of a mixed perovskite via in situ characterizations. Advanced Materials 2018; 30(28): 1801562. Shao SY, Cui Y, Duim H, et al. Enhancing the performance of the half tin and half lead perovskite solar cells by suppression of the bulk and interfacial charge recombination. Advanced Materials 2018; 30(35): 1803703. Sun HX, Deng KM, Zhu YY, et al. A novel conductive mesoporous layer with a dynamic two-step deposition strategy boosts efficiency of perovskite solar cells to 20%. Advanced Materials 2018; 30(28): 1801935. Ge QQ, Shao JY, Ding J, et al. A two-dimensional hole-transporting material for high-performance perovskite solar cells with 20% average efficiency. Angewandte Chemie-International Edition 2018; 57(34): 10959-10965. Hilt F, Hovish MQ, Rolston N, et al. Rapid route to efficient, scalable, and robust perovskite photovoltaics in air. Energy and Environmental Science 2018; 11(8): 2102-2113. Jung M, Shin TJ, Seo J, et al. Structural features and their functions in surfactant-armoured methylammonium lead iodide perovskites for highly efficient and stable solar cells. Energy and Environmental Science 2018; 11(8): 2188-2197. Luo JS, Xia JX, Yang H, et al. Toward high-efficiency, hysteresis-less, stable perovskite solar cells: Unusual doping of a hole-transporting material using a fluorine-containing hydrophobic Lewis acid. Energy and Environmental Science 2018; 11(8): 2035-2045 Zhang H, Ren XG, Chen XW, et al. Improving the stability and performance of perovskite solar cells via off-the-shelf post-device ligand treatment. Energy and Environmental Science 2018; 11(8): 2253-2262. Chen QS, Wu J, Ou XY, et al. All-inorganic perovskite nanocrystal scintillators. Nature 2018; 561(7721): 88. Lee JW, Dai ZH, Han TH, et al. 2D perovskite stabilized phase-pure formamidinium perovskite solar cells. Nature Communications 2018; 9: 3021. Lu SH, Zhou QH, Ouyang YX, et al. Accelerated discovery of stable lead-free hybrid organic-inorganic perovskites via machine learning. Nature Communications 2018; 9:3405. Park BW, Kedem N, Kulbak M, et al. Understanding how excess lead iodide precursor improves halide perovskite solar cell performance. Nature Communications 2018; 9: 3301. Yang D, Yang RX, Wang K, et al. High efficiency planar-type perovskite solar cells with negligible hysteresis using EDTA-complexed SnO2. Nature Communications 2018; 9: 3239. Jeon NJ, Na H, Jung EH, et al. A fluorene-terminated hole-transporting material for highly efficient and stable perovskite solar cells. Nature Energy 2018; 3(8): 682. Saidaminov MI, Kim J, Jain A, et al. Suppression of atomic vacancies via incorporation of isovalent small ions to increase the stability of halide perovskite solar cells in ambient air. Nature Energy 2018; 3(8): 648. Jia L, Minliang L, Letian D, et al. Thermochromic halide perovskite solar cells. Nature Materials 2018; 17(3): 261. Sahli F, Werner J, Kamino BA, et al. Fully textured monolithic perovskite/silicon tandem solar cells with 25.2% power conversion efficiency. Nature Materials 2018; 17(9): 820. Park J, Huang JL, Yun J, et al. The role of hydrogen from ALD-Al2O3 in kesterite Cu2ZnSnS4 solar cells: grain surface Advanced Energy Materials 2018; 8(23): M, V, T, et al. Improving with indium and in solar cells deposited at temperature on IEEE Journal of Photovoltaics 2018; 8(5): A, et al. materials for interface passivation of films. IEEE Journal of Photovoltaics 2018; 8(5): K, of and temperature on the electrical performance of thin-film solar cells. IEEE Journal of Photovoltaics 2018; 8(5): T, S, M, et al. and solar cell by with IEEE Journal of Photovoltaics 2018; 8(5): S, P, et al. degradation of solar cells: metal and IEEE Journal of Photovoltaics 2018; 8(5): MH, B, E, et al. of and on the of films. IEEE Journal of Photovoltaics 2018; 8(5): I, T, S, et al. and electronic in Journal of Applied Physics 2018; 124(8): Chen CY, Chen et al. 10% efficiency solar cells by introducing metal as contacts. Nano Energy 2018; 51: Ma YP, Li Feng Y, et al. grain boundaries of films and its effect on photovoltaic performance. Nano Energy 2018; 51: Yan C, Huang JL, Sun et al. Cu2ZnSnS4 solar cells with over 10% power conversion efficiency enabled by heterojunction treatment. Nature Energy 2018; 3(9): Han Meng L, et al. High-performance monolithic tandem solar cells. Science 2018; Ren S, Wang H, Li Y, et al. Rapid thermal on window layer for improved performance of solar cells. Solar Energy Materials and Solar Cells 2018; 187: D, O, M, et al. Effect of different Na on solar cells with Al2O3 rear passivation Solar Energy Materials and Solar Cells 2018; 187: X, Ren S, Li C, et al. Investigation of recombination mechanisms of solar cells with different Solar Energy Materials and Solar Cells 2018; 188: X, Li H, F, et al. solar cell with as the layer by a chemical deposition Solar Energy 2018; 171: RH, Lee et al. temperature of charge carrier in Acs Nano 2018; 12(8): H, M, Lee W, et al. Improved and efficiency of solar cells based on organic hole transport Advanced Energy Materials 2018; 8(23): Guo W, Sun B, et al. structure of a promising to the Advanced Functional Materials 2018; 28(32): novel electronic structure and application Advanced Materials 2018; 1800082. et al. Overcoming the ambient in photovoltaics. Advanced Materials 2018; 30(35): Gao XY, XY, Zhao X, et al. solar cells based on different metal counter Applied Physics Letters 2018; Lee SH, JH, et al. A hole-selective layer for efficient and stable solar cells. Energy and Environmental Science 2018; 11(8): et al. on lead halide perovskite for high-efficiency photovoltaics. Journal of the American Chemical Society 2018; Zheng W, Huang P, Gong ZL, et al. in lead halide perovskite Nature Communications 2018; 9: Zeng T, X, Feng S, et al. on TiO2 electron transport layer for efficient carrier extraction in photovoltaics. Solar Energy Materials and Solar Cells 2018; 188: 263-272. 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The effect of solar on the performance of PV Solar Energy 2018; 171: G, M, J, et al. performance and analysis of photovoltaic with different Solar Energy 2018; 171: S, P, S, et al. of the of and crystalline silicon photovoltaic under climate conditions. Solar Energy 2018; 171: E, A for for photovoltaic cells. Solar Energy 2018; 171: M, An improved based for PV under Solar Energy 2018; 171: G, et al. A to the photovoltaic in based on maximizing Renewable Energy 2019; 130: B, J, C. Photovoltaics and of Energy 2018; J, T, N, et al. to and the of solar power for Energy 2018; J, S, L, et al. and of and the Energy 2018; Zhang Xu Sun et al. using photovoltaic of Energy 2018; Z, Yan X, Zhao Yang D, et al. of generation and in IEEE on 2018; Yu of tandem photovoltaic in the Nature Energy 2018; 3(9): M, et al. assessment on PERC solar modules. Solar Energy Materials and Solar Cells 2018; 187: F, E, S, et al. Hybrid solar power system versus photovoltaic a analysis through a approach. 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DOI: https://doi.org/10.1002/pip.3092