Photovoltaics literature survey (No. 148)
At a Glance
Section titled âAt a Glanceâ| Metadata | Details |
|---|---|
| Publication Date | 2019-01-20 |
| Journal | Progress in Photovoltaics Research and Applications |
| Authors | Ziv Hameiri |
| Institutions | UNSW Sydney |
| Citations | 1 |
Abstract
Section titled âAbstractâIn 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 paperâs quality. If you have any suggestions please email Ziv Hameiri at [email protected]. Ripalda JM, Buencuerpo J, Garcia I. Solar cell designs by maximizing energy production based on machine learning clustering of spectral variations. Nature Communications 2018; 9: 5126. Neu J, Regan KP, Swierk JR, et al. Applicability of the thin-film approximation in terahertz photoconductivity measurements. Applied Physics Letters 2018; 113(23): 233901. Osayemwenre GO, Meyer EL, Taziwa R. Investigation of defects in crystalline silicon solar cells by confocal Raman spectroscopy. Energy and Environment 2018; 29(8): 1525. Gallardo-Saavedra S, Hernandez-Callejo L, Duque-Perez O. Image resolution influence in aerial thermographic inspections of photovoltaic plants. IEEE Transactions on Industrial Informatics 2018; 14(12): 5678. He YZ, Du BL, Huang SD. Noncontact electromagnetic induction excited infrared thermography for photovoltaic cells and modules inspection. IEEE Transactions on Industrial Informatics 2018; 14(12): 5585. Shirai H. Variation-free baseline with p-polarized Brewster incidence for infrared measurement of carbon impurities in silicon wafer. Japanese Journal of Applied Physics 2018; 57(12): 121301. Tayagaki T, Reichmuth SK, Helmers H, et al. Transient analysis of luminescent coupling effects in multijunction solar cells. Journal of Applied Physics 2018; 124(18): 183103. Tada K. What do apparent series and shunt resistances in solar cell estimated by I-V slope mean? Study with exact analytical expressions. Physica Status Solidi A-Applications and Materials Science 2018; 215(23): 1800448. Pearce P, Mellor A, Ekins-Daukes N. The importance of accurate determination of optical constants for the design of nanometallic light-trapping structures. Solar Energy Materials and Solar Cells 2019; 191: 133-140. Kwapil W, Wasmer S, Fell A, et al. Suns-ILIT: Contact-less determination of local solar cell current-voltage characteristics. Solar Energy Materials and Solar Cells 2019; 191: 71-77. Yu F, Huang G, Lin W, et al. An analysis for S-shaped I-V characteristics of organic solar cells using lumped-parameter equivalent circuit model. Solar Energy 2019; 177: 229-240. MĂŒhleisen W, Hirschl C, Brantegger G, et al. Scientific and economic comparison of outdoor characterisation methods for photovoltaic power plants. Renewable Energy 2019; 134: 321-329. Addonizio ML, Antonaia A, Fusco L. Plasma etched c-Si wafer with proper pyramid-like nanostructures for photovoltaic applications. Applied Surface Science 2019; 467: 143. Mullerova J, Scholtz L, Durisova J, et al. Angle- and polarization-resolved antireflection properties of black silicon prepared by electrochemical etching supported by external electric field. Applied Surface Science 2018; 461: 182. Sun ZM, Gupta MC. A study of laser-induced surface defects in silicon and impact on electrical properties. Journal of Applied Physics 2018; 124(22): 223103. Sperber D, Schwarz A, Herguth A, et al. Bulk- and surface-related degradation in lifetime samples made of Czochralski silicon passivated by plasma-enhanced chemical vapor deposited layer stacks. Physica Status Solidi A-Applications and Materials Science 2018; 215(24): 1800741. Temmler J, Polzin JI, Feldmann F, et al. Inline PECVD deposition of poly-Si-based tunnel oxide passivating contacts. Physica Status Solidi A-Applications and Materials Science 2018; 215(23): 1800449. Rahova J, Sampathkumar K, Vetushka A, et al. Local photovoltaic properties of graphene-silicon heterojunctions. Physica Status Solidi B-Basic Solid State Physics 2018; 255(12): 1800305. Yousef S, Tatariants M, Denafas J, et al. Sustainable industrial technology for recovery of Al nanocrystals, Si microparticles and Ag from solar cell wafer production waste. Solar Energy Materials and Solar Cells 2019; 191: 493-501. Xin Z, Ling ZP, Wang P, et al. Ultra-thin atomic layer deposited aluminium oxide tunnel layer passivated hole-selective contacts for silicon solar cells. Solar Energy Materials and Solar Cells 2019; 191: 164-174. Xie M, Yu X, Qiu X, et al. Light-soaking enhanced passivation of Al2O3 on crystalline silicon surface. Solar Energy Materials and Solar Cells 2019; 191: 350355. Shanmugam V, Chen N, Yan X, et al. Impact of the manufacturing process on the reverse-bias characteristics of high-efficiency n-type bifacial silicon wafer solar cells. Solar Energy Materials and Solar Cells 2019; 191: 117-122. Chen K, Zha J, Hu F, et al. MACE nanotexture process applicable for both single-crystalline and multicrystalline diamond-wire sawn Si solar cells. Solar Energy Materials and Solar Cells 2019; 191: 1-8. Tao K, Jiang S, Jia R, et al. The impact of indium tin oxide deposition and post annealing on the passivation property of TOPCon solar cells. Solar Energy 2018; 176: 241-247. Paviet-Salomon B, Tomasi A, Lachenal D, et al. Interdigitated back contact silicon heterojunction solar cells featuring an interband tunnel junction enabling simplified processing. Solar Energy 2018; 175: 60-67. Descoeudres A, AllebĂ© C, Badel N, et al. Low-temperature processes for passivation and metallization of high-efficiency crystalline silicon solar cells. Solar Energy 2018; 175: 54-59. Altermatt PP, Xiong Z, He Q, et al. High-performance p-type multicrystalline silicon (mc-Si): Its characterization and projected performance in PERC solar cells. Solar Energy 2018; 175: 68-74. Pavlikov AV, Forsh PA, Svyakhovskiy SE, et al. Giant enhancement of free charge carrier concentration in boron-doped amorphous hydrogenated silicon under femtosecond laser crystallization. Applied Physics Letters 2018; 113(20): 203103. Canteli D, Torres I, Fernandez S, et al. Photon-collection improvement from laser-textured AZO front-contact in thin-film solar cells. Applied Surface Science 2019; 463: 775. Scholtz L, Sutta P, Calta P, et al. Investigation of barium titanate thin films as simple antireflection coatings for solar cells. Applied Surface Science 2018; 461: 249. Hadmojo WT, Lee UH, Yim D, et al. High-performance near-infrared absorbing n-type porphyrin acceptor for organic solar cells. Acs Applied Materials and Interfaces 2018; 10(48): 41344. Liu XH, Zou Y, Wang HQ, et al. High-performance all-polymer solar cells with a high fill factor and a broad tolerance to the donor/acceptor ratio. Acs Applied Materials and Interfaces 2018; 10(44): 38302. Cha H, Tan CH, Wu JY, et al. An analysis of the factors determining the efficiency of photocurrent generation in polymer: Nonfullerene acceptor solar cells. Advanced Energy Materials 2018; 8(32): 1801537. Zhang L, Xu XB, Lin BJ, et al. Achieving balanced crystallinity of donor and acceptor by combining blade-coating and ternary strategies in organic solar cells. Advanced Materials 2018; 30(51): 1805041. Chiykowski VA, Cao Y, Tan HR, et al. Precise control of thermal and redox properties of organic hole-transport materials. Angewandte Chemie-International Edition 2018; 57(47): 15529. Huo Y, Gong XT, Lau TK, et al. Dual-accepting-unit design of donor material for all-small-molecule organic solar cells with efficiency approaching 11%. Chemistry of Materials 2018; 30(23): 8661. Savikhin V, Babics M, Neophytou M, et al. Impact of polymer side chain modification on OPV morphology and performance. Chemistry of Materials 2018; 30(21): 7872. Liu T, Luo ZH, Fan QP, et al. Use of two structurally similar small molecular acceptors enabling ternary organic solar cells with high efficiencies and fill factors. Energy and Environmental Science 2018; 11(11): 3275. Nian L, Kan YY, Wang HT, et al. Ternary non-fullerene polymer solar cells with 13.51% efficiency and a record-high fill factor of 78.13%. Energy and Environmental Science 2018; 11(12): 3392. Balderrama VS, Sanchez JG, Lastra G, et al. High-efficiency organic solar cells based on a halide salt and polyfluorene polymer with a high alignment-level of the cathode selective contact. Journal of Materials Chemistry A 2018; 6(45): 22534. Gao BW, Yao HF, Hou JX, et al. Multicomponent nonfullerene acceptors with tunable bandgap structures for efficient organic solar cells. Journal of Materials Chemistry A 2018; 6(46): 23644. Jeong G, Jung S, Choi Y, et al. A highly robust and stable graphene-encapsulated Cu-grid hybrid transparent electrode demonstrating superior performance in organic solar cells. Journal of Materials Chemistry A 2018; 6(48): 24805. Wang FJ, Nakano K, Yoshida H, et al. Effects of end-on oriented polymer chains at the donor/acceptor interface in organic solar cells. Journal of Materials Chemistry A 2018; 6(45): 22889. Zhong L, Bin HJ, Li YX, et al. Ternary nonfullerene polymer solar cells with a high crystallinity n-type organic semiconductor as the second acceptor. Journal of Materials Chemistry A 2018; 6(48): 24814. Ashokan A, Wang TH, Ravva MK, et al. Impact of solution temperature-dependent aggregation on the solid-state packing and electronic properties of polymers for organic photovoltaics. Journal of Materials Chemistry C 2018; 6(48): 13162. Li JF, Liang ZZ, Wang YF, et al. Enhanced efficiency of polymer solar cells through synergistic optimization of mobility and tuning donor alloys by adding high-mobility conjugated polymers. Journal of Materials Chemistry C 2018; 6(41): 11015. Lyu CK, Zheng F, Babu BH, et al. Functionalized graphene oxide enables a high-performance bulk heterojunction organic solar cell with a thick active layer. Journal of Physical Chemistry Letters 2018; 9(21): 6238. Hu T, Lv XL, Cheng XF, et al. Self-assembly monolayers manipulate the power conversion processes in organic photovoltaics. Journal of Power Sources 2019; 409: 66. Xing W, Ye P, Lu J, et al. Tellurophene-based metal-organic framework nanosheets for high-performance organic solar cells. Journal of Power Sources 2018; 401: 13. Wang ZL, Yang Y, Zhang LF, et al. Modulation-doped ZnO as high performance electron-selective layer for efficient silicon heterojunction solar cells. Nano Energy 2018; 54: 99. Huang WC, Chang SY, Cheng P, et al. High efficiency nonfullerene organic tandem photovoltaics based on ternary blend subcells. Nano Letters 2018; 18(12): 7977. Chen XK, Coropceanu V, Bredas JL. Assessing the nature of the charge-transfer electronic states in organic solar cells. Nature Communications 2018; 9: 5295. Fan BB, Du XY, Liu F, et al. Fine-tuning of the chemical structure of photoactive materials for highly efficient organic photovoltaics. Nature Energy 2018; 3(12): 1051. Hedley GJ, Steiner F, Vogelsang J, et al. Fluctuations in the emission polarization and spectrum in single chains of a common conjugated polymer for organic photovoltaics. Small 2018; 14(51): 1804312. Cheng YC, Yang GS, Jiang HR, et al. Organic sensitizers with extended conjugation frameworks as cosensitizers of porphyrins for developing efficient dye-sensitized solar cells. Acs Applied Materials and Interfaces 2018; 10(45): 38880. Liu IP, Lin WH, Tseng-Shan CM, et al. Importance of compact blocking layers to the performance of dye-sensitized solar cells under ambient light conditions. Acs Applied Materials and Interfaces 2018; 10(45): 38900. Kato N, Moribe S, Shiozawa M, et al. Improved conversion efficiency of 10% for solid-state dye-sensitized solar cells utilizing P-type semiconducting CuI and multidye consisting of novel porphyrin dimer and organic dyes. Journal of Materials Chemistry A 2018; 6(45): 22508-22512. Krishna JVS, Krishna NV, Chowdhury TH, et al. Kinetics of dye regeneration in liquid electrolyte unveils efficiency of 10.5% in dye-sensitized solar cells. Journal of Materials Chemistry C 2018; 6(42): 11444. Zhang WY, Heng PP, Su HS, et al. Rational design of high-efficiency organic dyes in dye-sensitized solar cells by multiscale simulations. Journal of Physical Chemistry C 2018; 122(44): 25219. Yuan HW, Zhao YY, Wang YD, et al. Sonochemistry-assisted black/red phosphorus hybrid quantum dots for dye-sensitized solar cells. Journal of Power Sources 2019; 410: 53. Meng XT, Yu C, Zhang XP, et al. Active sites-enriched carbon matrix enables efficient triiodide reduction in dye-sensitized solar cells: An understanding of the active centers. Nano Energy 2018; 54: 138. James S, Contractor R. Study on nature-inspired fractal design-based flexible counter electrodes for dye-sensitized solar cells fabricated using additive manufacturing. Scientific Reports 2018; 8: 17032. Xie J, Yuan H, Wang W, et al. TiCl4-free 100.6-cm2 active area dye-sensitized solar cells with approximately 8% power conversion efficiency. Solar Energy 2018; 176: 320-324. Su R, Ashraf S, El-Shafei A. Structure-property relationships: âDouble-tail versus double-flapâ ruthenium complex structures for high efficiency dye-sensitized solar cells. Solar Energy 2019; 177: 724-736. Sarker S, Kim DM. Measurement and simulation of current-voltage relation in dye-sensitized solar cells with reduced graphene oxide at the counter electrodes. Solar Energy 2018; 176: 656-662. Mo L-E, Li Z-Q, Ding Y-C, et al. Facile synthesis of TiO2 microspheres via solvothermal alcoholysis method for high performance dye-sensitized solar cells. Solar Energy 2019; 177: 448-454. Li G, Sheng L, Li T, et al. Engineering flexible dye-sensitized solar cells for portable electronics. Solar Energy 2019; 177: 80-98. Gao X, Kong C-p, Jia R, et al. Influence of one-dimensional TiO2 nanotube on interfacial electron transfer in dye-sensitized solar cells: Insights from theoretical investigation. Solar Energy 2018; 176: 545-555. Agasti A, Nemala SS, Mallick S, et al. Stability study of co-electrodeposited CZTS counter electrode for dye sensitized solar cells. Solar Energy 2018; 176: 325-333. Najafi L, Taheri B, Martin-Garcia B, et al. MoS2 quantum dot/graphene hybrids for advanced interface engineering of a CH3NH3PbI3 perovskite solar cell with an efficiency of over 20%. Acs Nano 2018; 12(11): 10736. Hsu HL, Hsiao HT, Juang TY, et al. Carbon nanodot additives realize high-performance air-stable p-i-n perovskite solar cells providing efficiencies of up to 20.2%. Advanced Energy Materials 2018; 8(34): 1870147. Magomedov A, Al-Ashouri A, Kasparavicius E, et al. Self-assembled hole transporting monolayer for highly efficient perovskite solar cells. Advanced Energy Materials 2018; 8(32): 1801892. Mashhoun S, Yi H, Haiwei C, et al. Resolving a critical instability in perovskite solar cells by designing a scalable and printable carbon based electrode-interface architecture. Advanced Energy Materials 2018; 8(31): 1802085. Petrus ML, Schutt K, Sirtl MT, et al. New generation hole transporting materials for perovskite solar cells: Amide-based small-molecules with nonconjugated backbones. Advanced Energy Materials 2018; 8(32): 1801605. Du T, Burgess CH, Lin CT, et al. Probing and controlling intragrain crystallinity for improved low temperature-processed perovskite solar cells. Advanced Functional Materials 2018; 28(51): 1803943. Gao HF, Feng JG, Pi YY, et al. Bandgap engineering of single-crystalline perovskite arrays for high-performance photodetectors. Advanced Functional Materials 2018; 28(46): 1804349. Lin XF, Chesman ASR, Raga SR, et al. Effect of grain cluster size on back-contact perovskite solar cells. Advanced Functional Materials 2018; 28(45): 1805098. Huang JM, Lai ML, Lin J, et al. Rich chemistry in inorganic halide perovskite nanostructures. Advanced Materials 2018; 30(48): 1802856. Zhao PJ, Kim BJ, Ren XD, et al. Antisolvent with an ultrawide processing window for the one-step fabrication of efficient and large-area perovskite solar cells. Advanced Materials 2018; 30(49): 1802763. Elseman AM, Sharmoukh W, Sajid S, et al. Superior stability and efficiency over 20% perovskite solar cells achieved by a novel molecularly engineered rutin-AgNPs/thiophene copolymer. Advanced Science 2018; 5(11): 1800568. Fang ZS, He HP, Gan L, et al. Understanding the role of lithium doping in reducing nonradiative loss in lead halide perovskites. Advanced Science 2018; 5(12): 1800736. Avila J, Momblona C, Boix P, et al. High voltage vacuum-deposited CH3NH3PbI3-CH3NH3PbI3 tandem solar cells. Energy and Environmental Science 2018; 11(11): 3292. Choi K, Lee J, Kim HI, et al. Thermally stable, planar hybrid perovskite solar cells with high efficiency. Energy and Environmental Science 2018; 11(11): 3238. Jost M, Kohnen E, Morales-Vilches AB, et al. Textured interfaces in monolithic perovskite/silicon tandem solar cells: Advanced light management for improved efficiency and energy yield. Energy and Environmental Science 2018; 11(12): 3511. Zhu XJ, Xu Z, Zuo SN, et al. Vapor-fumigation for record efficiency two-dimensional perovskite solar cells with superior stability. Energy and Environmental Science 2018; 11(12): 3349. Kearney K, Seo G, Matsushima T, et al. Computational analysis of the interplay between deep level traps and perovskite solar cell efficiency. Journal of the American Chemical Society 2018; 140(46): 15655. Giuri A, Masi S, Listorti A, et al. Polymeric rheology modifier allows single-step coating of perovskite ink for highly efficient and stable solar cells. Nano Energy 2018; 54: 400. Li JS, Jiu TG, Chen SQ, et al. Graphdiyne as a host active material for perovskite solar cell application. Nano Letters 2018; 18(11): 6941. Chen SL, Zhang XW, Zhao JJ, et al. Atomic scale insights into structure instability and decomposition pathway of methylammonium lead iodide perovskite. Nature Communications 2018; 9: 4807. Cheng B, Li TY, Wei PC, et al. Layer-edge device of two-dimensional hybrid perovskites. Nature Communications 2018; 9: 5196. Ke WJ, Spanopoulos I, Stoumpos CC, et al. Myths and reality of HPbI3 in halide perovskite solar cells. Nature Communications 2018; 9: 4785. Lin YZ, Chen B, Fang YJ, et al. Excess charge-carrier induced instability of hybrid perovskites. Nature Communications 2018; 9: 4981. Turren-Cruz SH, Hagfeldt A, Saliba M. Methylammonium-free, high-performance, and stable perovskite solar cells on a planar architecture. Science 2018; 362(6413): 449. Khan F, Kim JH. N-functionalized graphene quantum dots with ultrahigh quantum yield and for solar cells. Acs 2018; 5(11): S, SR, et al. films with fabricated by economic and Acs Sustainable Chemistry and Engineering 2018; A, C, et al. solar cells with lithium Advanced Energy Materials 2018; 8(34): SH, S, S, et al. effects of in CZTS solar cells with over 10% efficiency. Advanced Energy Materials 2018; 8(32): JS, Kim S, SN, et al. voltage in solar cells by interface bandgap Applied Physics Letters 2018; Zhu H, Z, X, et al. and electrodes for thin solar cells. Applied Surface Science 2019; Zhang Tao JH. An efficiency photovoltaic device fabricated via a Journal of Materials Chemistry C 2018; 6(48): M, A, et al. analysis of the of thin films by and Raman spectroscopy. Physica Status Solidi A-Applications and Materials Science 2018; 215(24): E, E, M, et al. and in single Scientific Reports 2018; 8: S, R, N. Influence of the annealing and on the properties of based solar cells. Solar Energy Materials and Solar Cells 2019; 191: G, BL, V, et al. of the photocurrent and efficiency of solar cells the contact using a ZnO layer. Solar Energy Materials and Solar Cells 2019; 191: L, S, et al. solar cells on low Solar Energy 2018; 175: Yan Q, Cheng S, Li H, et al. High flexible solar cells by Solar Energy 2019; 177: for critical thin A Solar Energy 2018; 176: A, E, solar cells: A Solar Energy 2018; 175: Ren S, Li H, C, et al. modification to electron by deposition of a on in solar cells. Solar Energy 2019; 177: S, S, L, et al. An on the grain and the of of based thin films by Solar Energy 2018; 176: S, N, from annealing of and Solar Energy 2018; 175: A, G, N. and of the thin solar cells. Solar Energy 2018; 175: C, Schwarz T, et al. of properties from in thin solar cells. Solar Energy 2018; 175: An R, Zhang Zou et al. and processes in perovskite quantum Acs Applied Materials and Interfaces 2018; 10(45): JM, N, et al. quantum solar cells stability with a semiconducting carbon the Advanced Materials Interfaces 2018; R, Huang YZ, et al. and thin deposition and in quantum solar cells. Transactions 2018; Huang F, H, Wang Y, et al. ZnO microspheres with passivation layer for high efficiency quantum sensitized solar cells. Journal of Power Sources 2018; 401: N, et al. and traps in and quantum The importance of Journal of the American Chemical Society 2018; 140(46): Xu J, et al. charge transfer and carrier in quantum Nano Letters 2018; 18(11): D, Zhao et al. measurement of electronic structure in single quantum dots of Small 2018; 14(51): Tao M. A control for improved efficiency in photovoltaic through Applied Energy 2018; L, N, T, et al. Assessing the of as a for photovoltaic applications. Applied Energy 2018; T, Zhao JX, Li and analysis of solar photovoltaic with Applied Energy 2018; et al. A high performance method for determining the of cells and modules based on Applied Energy 2018; J, F, A framework to of photovoltaic to power Applied Energy 2018; YJ, YJ, et al. the of solar photovoltaic Energy and economic in Applied Energy 2018; A, K, S, et al. energy management for photovoltaic power including hybrid energy in applications. Energy 2018; R, A, et al. An efficient for of photovoltaic cell Energy and 2019; Chen Wu et al. based for arrays using voltage and Energy and 2018; JS, et al. A simplified for energy performance of photovoltaic Energy and 2018; 177: H, M, A, et al. New analytical for effects of and on of photovoltaic solar Energy and 2018; 177: Yang B, Yu T, Zhang et al. based for power of by Energy and 2019; JH. power for the optimization of photovoltaic power processing IEEE Transactions on Power 2019; Zhang J, et al. A for from improved solar power in power IEEE Transactions on 2018; Y, H, K, et al. Effect of property of on degradation of crystalline silicon photovoltaic modules under of and Japanese Journal of Applied Physics 2018; 57(12): S, K, A, et al. and of degradation of n-type photovoltaic Japanese Journal of Applied Physics 2018; 57(12): V, L, D, et al. and light A impact study on dye-sensitized and silicon heterojunction solar cells applications. Solar Energy Materials and Solar Cells 2019; 191: C, et al. for the of of Solar Energy Materials and Solar Cells 2019; 191: Zhu H, Lu L, Yao J, et al. for photovoltaic arrays based on clustering and model. Solar Energy 2018; 176: Zhao B, Hu M, X, et al. analysis of enhanced of solar cells based on a silicon photovoltaic Solar Energy 2018; 176: M, et al. bifacial is Solar Energy 2018; 176: P, of of photovoltaic A chemical on process Solar Energy 2019; 177: J, A, performance of bifacial silicon modules under the Solar Energy 2019; 177: Yang Liang Hsu et al. Enhanced efficiency of photovoltaic by a with energy Renewable Energy 2019; 134: J, M, R, et al. A for solar spectral in the spectral of thin-film photovoltaic Renewable Energy 2019; R, L, et al. design with the of on the Renewable Energy 2019; R, the efficiency of photovoltaic Renewable and Sustainable Energy 2019; R, Power for efficient of photovoltaic in solar Renewable and Sustainable Energy 2019; A, M, L. 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