Photovoltaics literature survey (No. 187)

IF 8 2区 材料科学 Q1 ENERGY & FUELS
Ziv Hameiri
{"title":"Photovoltaics literature survey (No. 187)","authors":"Ziv Hameiri","doi":"10.1002/pip.3757","DOIUrl":null,"url":null,"abstract":"<p>In order to help readers stay up-to-date in the field, each issue of <i>Progress in Photovoltaics</i> 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 <i>IEEE Journal of Photovoltaics</i>, <i>Solar Energy Materials and Solar Cells</i>, <i>Renewable Energy</i>, <i>Renewable and Sustainable Energy Reviews</i>, <i>Journal of Applied Physics</i>, and <i>Applied Physics Letters</i>. 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 <span>[email protected]</span>.</p><p>Surmenev RA, Surmeneva MA. <b>The influence of the flexoelectric effect on materials properties with the emphasis on photovoltaic and related applications: A review.</b> <i>Materials Today</i> 2023; <b>67</b>: 256–298.</p><p>Röhr JA, Sartor BE, Lipton J, <i>et al.</i> <b>A dive into underwater solar cells.</b> <i>Nature Photonics</i> 2023; <b>17</b>(9): 747–754.</p><p>Henry R, Balar N, Ade H. <b>In-situ ellipsometry for the determination of thermal transitions and relaxations in organic photovoltaic materials.</b> <i>Chemistry of Materials</i> 2023; <b>35</b>(18): 7406–7421.</p><p>Cetinbas I, Tamyurek B, Demirtas M. <b>Parameter extraction of photovoltaic cells and modules by hybrid white shark optimizer and artificial rabbits optimization.</b> <i>Energy Conversion and Management</i> 2023; <b>296</b>: 117621.</p><p>Zahmatkeshsaredorahi A, Jakob DS, Fang H, <i>et al.</i> <b>Pulsed force Kelvin probe force microscopy through integration of lock-in detection.</b> <i>Nano Letters</i> 2023; <b>23</b>(19): 8953–8959.</p><p>Chu MQ, Jiang Z, Wojcik M, <i>et al.</i> <b>Probing three-dimensional mesoscopic interfacial structures in a single view using multibeam x-ray coherent surface scattering and holography imaging.</b> <i>Nature Communications</i> 2023; <b>14</b>(1): 5795.</p><p>Saliba M, Unger E, Etgar L, <i>et al.</i> <b>A systematic discrepancy between the short circuit current and the integrated quantum efficiency in perovskite solar cells.</b> <i>Nature Communications</i> 2023; <b>14</b>(1): 5445.</p><p>Mateo Romero HF, Hernández-Callejo L, González Rebollo MÁ, <i>et al.</i> <b>Optimized estimator of the output power of PV cells using EL images and I–V curves.</b> <i>Solar Energy</i> 2023; <b>265</b>: 112089.</p><p>Mintairov MA, Evstropov VV, Mintairov SA, <i>et al.</i> <b>Current invariant as fundamental relation between saturation currents and band gaps for semiconductor solar cells.</b> <i>Solar Energy Materials and Solar Cells</i> 2024; <b>264</b>: 112619.</p><p>Liu XN, Xu ZY, Yan Y, <i>et al.</i> <b>Full-area i-a-Si:H/ATO/Mg electron-selective contacts for silicon solar cells.</b> <i>Acs Applied Energy Materials</i> 2023; <b>6</b>(18): 9446–9454.</p><p>Mo SI, Choi S, An JH, <i>et al.</i> <b>Design rule of electron- and hole-selective contacts for polycrystalline silicon-based passivating contact solar cells.</b> <i>Acs Applied Materials and Interfaces</i> 2023; <b>15</b>(40): 46849–46860.</p><p>Shehata MM, Macdonald DH, Black LE. <b>Dramatic reduction of silicon surface recombination by ALD TiO</b><sub><b>x</b></sub> <b>capping layer from TiCl</b><sub><b>4</b></sub> <b>and H</b><sub><b>2</b></sub><b>O: The role of chlorine.</b> <i>Acs Applied Materials and Interfaces</i> 2023; <b>15</b>(39): 46504–46512.</p><p>Li YS, Chen ZW, Zhang B, <i>et al.</i> <b>Construction of efficient silicon solar cells through polymetallic oxidation–reduction triggered by thermite reaction.</b> <i>Nano Energy</i> 2023; <b>116</b>: 108801.</p><p>Mahmood Fi, Li F, Hacke P, <i>et al.</i> <b>Susceptibility to polarization type potential induced degradation in commercial bifacial p-PERC PV modules.</b> <i>Progress in Photovoltaics: Research and Applications</i> 2023; <b>31</b>(11): 1078–1090.</p><p>Rudolph D, Messmer T, Timofte T, <i>et al.</i> <b>Improvement of solder interconnections applied on back contact solar cells with low-temperature copper paste busbars.</b> <i>Solar Energy Materials and Solar Cells</i> 2024; <b>264</b>: 112603.</p><p>Jhou JC, Gaurav A, Lin HT, <i>et al.</i> <b>Bandgap tunable perovskite for Si-based triple junction tandem solar cell: Numerical analysis-aided experimental investigation.</b> <i>Acs Applied Energy Materials</i> 2023; <b>6</b>(18): 9434–9445.</p><p>Wright M, Stefani BV, Jones TW, <i>et al.</i> <b>Design considerations for the bottom cell in perovskite/silicon tandems: A terawatt scalability perspective.</b> <i>Energy and Environmental Science</i> 2023; <b>16</b>(10): 4164–4190.</p><p>Xu ZJ, Bristow H, Babics M, <i>et al.</i> <b>Reverse-bias resilience of monolithic perovskite/silicon tandem solar cells.</b> <i>Joule</i> 2023; <b>7</b>(9): 1992–2002.</p><p>Jang J, Kim JH, Lee S, <i>et al.</i> <b>Efficient flexible organic solar cells with a low-temperature-processed Al-doped zinc oxide electron transport layer.</b> <i>Acs Applied Energy Materials</i> 2023; <b>6</b>(18): 9778–9787.</p><p>Khandelwal K, Shankar SS, Malhotra P, <i>et al.</i> <b>Unraveling the Impact of thickness on active layer morphology and device performance of semitransparent organic solar cells: A comprehensive study.</b> <i>Acs Applied Energy Materials</i> 2023; <b>6</b>(19): 10078–10087.</p><p>Kumagai N, Shimizu T, Minoda H, <i>et al.</i> <b>Visualization of tens of nanometers spaced donor: Acceptor bulk heterojunctions across submicrometer-square cross sections of organic photovoltaic cells.</b> <i>Acs Applied Energy Materials</i> 2023; <b>6</b>(18): 9363–9370.</p><p>Wang J, Zhang CF, Lin Y, <i>et al.</i> <b>Improving performance of organic photovoltaic devices under low illuminations.</b> <i>Acs Applied Energy Materials</i> 2023; <b>6</b>(19): 10163–10171.</p><p>Zhang FH, Yan YJ, Li MD, <i>et al.</i> <b>Efficient ternary indoor organic photovoltaics with fullerene derivative as the host acceptor and nonfullerene material as the guest acceptor.</b> <i>Acs Applied Energy Materials</i> 2023; <b>6</b>(19): 10137–10146.</p><p>Chen QL, Huang H, Ran GL, <i>et al.</i> <b>Improving the performance of layer-by-layer organic solar cells by n-doping of the acceptor layer.</b> <i>Acs Applied Materials and Interfaces</i> 2023; <b>15</b>(39): 46138–46147.</p><p>Sun FB, Wang XC, Wan M, <i>et al.</i> <b>High miscibility-induced reduction of trap density in all-polymer solar cells using hybrid cyclohexyl-hexyl side chains.</b> <i>Advanced Functional Materials</i> 2023; <b>33</b>: 2306791.</p><p>Guo CH, Fu YW, Li DH, <i>et al.</i> <b>A polycrystalline polymer donor as pre-aggregate toward ordered molecular aggregation for 19.3% efficiency binary organic solar cells.</b> <i>Advanced Materials</i> 2023; <b>35</b>: 2304921.</p><p>Cui Y, Zhao C, Souza JPA, <i>et al.</i> <b>Eliminating the imbalanced mobility bottlenecks via reshaping internal potential distribution in organic photovoltaics.</b> <i>Advanced Science</i> 2023; <b>10</b>(29): 2302880.</p><p>Li H, Gao T, He DX, <i>et al.</i> <b>Flashing ratchet effect for driving carriers to accelerate directional migration in organic photovoltaic devices.</b> <i>Applied Physics Letters</i> 2023; <b>123</b>(10): 103902.</p><p>Lewinska G, Kanak J, Danel KS, <i>et al.</i> <b>Effect of benzene-based dyes on optothermal properties of active layers for ternary organic solar cells.</b> <i>Applied Surface Science</i> 2023; <b>641</b>: 158535.</p><p>Kong XY, Zhan LL, Li SX, <i>et al.</i> <b>Spontaneous vertical phase distribution of multi-acceptors system enables high-efficiency organic photovoltaics in non-halogenated solvent and large-area module application.</b> <i>Chemical Engineering Journal</i> 2023; <b>473</b>: 145201.</p><p>Li MY, Wu HB, Wang J, <i>et al.</i> <b>Reducing voltage losses in organic solar cells based on fluorinated acceptors.</b> <i>Chemical Engineering Journal</i> 2023; <b>474</b>: 145390.</p><p>Wang HQ, Yang DB, Ding PF, <i>et al.</i> <b>Dual Forster resonance energy transfer effects enables high photocurrent density and high fill factor in ternary organic solar cells.</b> <i>Chemical Engineering Journal</i> 2023; <b>474</b>: 145395.</p><p>Smeets S, Liu Q, Vanderspikken J, <i>et al.</i> <b>Structurally pure and reproducible polymer materials for high-performance organic solar cells.</b> <i>Chemistry of Materials</i> 2023; <b>35</b>(19): 8158–8169.</p><p>Siddika S, Peng ZX, Balar N, <i>et al.</i> <b>Molecular interactions that drive morphological and mechanical stabilities in organic solar cells.</b> <i>Joule</i> 2023; <b>7</b>(7): 1593–1608.</p><p>Kim W, Oh J, Park J, <i>et al.</i> <b>Building-up relations between intra- and intermolecular interactions, miscibility, and performance for low-cost, efficient fully non-fused acceptor-based organic solar cells.</b> <i>Nano Energy</i> 2023; <b>117</b>: 108853.</p><p>Jiang YY, Li YX, Liu F, <i>et al.</i> <b>Suppressing electron–phonon coupling in organic photovoltaics for high-efficiency power conversion.</b> <i>Nature Communications</i> 2023; <b>14</b>(1): 5079.</p><p>Wang YM, Gao F. <b>Mechanisms for improved open-circuit voltage in ternary organic solar cells.</b> <i>Nature Energy</i> 2023; <b>8</b>(9): 919–920.</p><p>Tan H, Fan WX, Zhu MB, <i>et al.</i> <b>Nonfused ring electron acceptors for ternary polymer solar cells with low energy loss and efficiency over 18%.</b> <i>Small</i> 2023; 2304368.</p><p>Zhou HR, Lee HJ, Masud M, <i>et al.</i> <b>Synergistic effect of size-tailored structural engineering and postinterface modification for highly efficient and stable dye-sensitized solar cells.</b> <i>Acs Applied Materials and Interfaces</i> 2023; <b>15</b>(37): 43835–43844.</p><p>Speranza R, Zaccagnini P, Scalia A, <i>et al.</i> <b>Pouch-sealing as an effective way to fabricate flexible dye-sensitized solar cells and their integration with supercapacitors.</b> <i>Journal of Power Sources</i> 2023; <b>583</b>: 233581.</p><p>Yoo K, Kaliamurthy AK, Lee JJ, <i>et al.</i> <b>PVP/PEG polymer blend based electrolytes for quasi-solid-state dye-sensitized solar cells operating at low temperature.</b> <i>Journal of Power Sources</i> 2023; <b>583</b>: 233568.</p><p>Alizadeh A, Roudgar-Amoli M, Shariatinia Z, <i>et al.</i> <b>Recent developments of perovskites oxides and spinel materials as platinum-free counter electrodes for dye-sensitized solar cells: A comprehensive review.</b> <i>Renewable and Sustainable Energy Reviews</i> 2023; <b>187</b>: 113770.</p><p>Gianola G, Speranza R, Bella F, <i>et al.</i> <b>Homo-tandem-bifacial dye-sensitized solar cell: A new paradigm to boost photoconversion efficiency above limit.</b> <i>Solar Energy</i> 2023; <b>265</b>: 112116.</p><p>Scarano V, Gontrani L, Zarate AYS, <i>et al.</i> <b>A new push–pull dye for semi-transparent p-type dye-sensitized solar cells: Tuning conjugation by sexithiophene chain engineering.</b> <i>Solar Energy</i> 2023; <b>265</b>: 112143.</p><p>Chen JW, Wu C, Wang MH, <i>et al.</i> <b>Involving hydroxyl-rich D-glucamine to address hole extraction interfacial issues toward efficient and stable tin-based perovskite solar cells.</b> <i>Acs Applied Energy Materials</i> 2023; <b>6</b>(19): 9815–9823.</p><p>Magliano E, Mariani P, Agresti A, <i>et al.</i> <b>Semitransparent perovskite solar cells with ultrathin protective buffer layers.</b> <i>Acs Applied Energy Materials</i> 2023; <b>6</b>(20): 10340–10353.</p><p>Majhi T, Sridevi M, Jain S, <i>et al.</i> <b>Insight into controlled surface passivation of PEDOT:PSS for defect density modulation and efficient charge transport for perovskite solar cells.</b> <i>Acs Applied Energy Materials</i> 2023; 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Analysis of an evolutionary game.</b> <i>Solar Energy</i> 2023; <b>265</b>: 112136.</p>","PeriodicalId":223,"journal":{"name":"Progress in Photovoltaics","volume":"32 1","pages":"56-60"},"PeriodicalIF":8.0000,"publicationDate":"2023-12-10","publicationTypes":"Journal Article","fieldsOfStudy":null,"isOpenAccess":false,"openAccessPdf":"https://onlinelibrary.wiley.com/doi/epdf/10.1002/pip.3757","citationCount":"0","resultStr":null,"platform":"Semanticscholar","paperid":null,"PeriodicalName":"Progress in Photovoltaics","FirstCategoryId":"88","ListUrlMain":"https://onlinelibrary.wiley.com/doi/10.1002/pip.3757","RegionNum":2,"RegionCategory":"材料科学","ArticlePicture":[],"TitleCN":null,"AbstractTextCN":null,"PMCID":null,"EPubDate":"","PubModel":"","JCR":"Q1","JCRName":"ENERGY & FUELS","Score":null,"Total":0}
引用次数: 0

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].

Surmenev RA, Surmeneva MA. The influence of the flexoelectric effect on materials properties with the emphasis on photovoltaic and related applications: A review. Materials Today 2023; 67: 256–298.

Röhr JA, Sartor BE, Lipton J, et al. A dive into underwater solar cells. Nature Photonics 2023; 17(9): 747–754.

Henry R, Balar N, Ade H. In-situ ellipsometry for the determination of thermal transitions and relaxations in organic photovoltaic materials. Chemistry of Materials 2023; 35(18): 7406–7421.

Cetinbas I, Tamyurek B, Demirtas M. Parameter extraction of photovoltaic cells and modules by hybrid white shark optimizer and artificial rabbits optimization. Energy Conversion and Management 2023; 296: 117621.

Zahmatkeshsaredorahi A, Jakob DS, Fang H, et al. Pulsed force Kelvin probe force microscopy through integration of lock-in detection. Nano Letters 2023; 23(19): 8953–8959.

Chu MQ, Jiang Z, Wojcik M, et al. Probing three-dimensional mesoscopic interfacial structures in a single view using multibeam x-ray coherent surface scattering and holography imaging. Nature Communications 2023; 14(1): 5795.

Saliba M, Unger E, Etgar L, et al. A systematic discrepancy between the short circuit current and the integrated quantum efficiency in perovskite solar cells. Nature Communications 2023; 14(1): 5445.

Mateo Romero HF, Hernández-Callejo L, González Rebollo MÁ, et al. Optimized estimator of the output power of PV cells using EL images and I–V curves. Solar Energy 2023; 265: 112089.

Mintairov MA, Evstropov VV, Mintairov SA, et al. Current invariant as fundamental relation between saturation currents and band gaps for semiconductor solar cells. Solar Energy Materials and Solar Cells 2024; 264: 112619.

Liu XN, Xu ZY, Yan Y, et al. Full-area i-a-Si:H/ATO/Mg electron-selective contacts for silicon solar cells. Acs Applied Energy Materials 2023; 6(18): 9446–9454.

Mo SI, Choi S, An JH, et al. Design rule of electron- and hole-selective contacts for polycrystalline silicon-based passivating contact solar cells. Acs Applied Materials and Interfaces 2023; 15(40): 46849–46860.

Shehata MM, Macdonald DH, Black LE. Dramatic reduction of silicon surface recombination by ALD TiOx capping layer from TiCl4 and H2O: The role of chlorine. Acs Applied Materials and Interfaces 2023; 15(39): 46504–46512.

Li YS, Chen ZW, Zhang B, et al. Construction of efficient silicon solar cells through polymetallic oxidation–reduction triggered by thermite reaction. Nano Energy 2023; 116: 108801.

Mahmood Fi, Li F, Hacke P, et al. Susceptibility to polarization type potential induced degradation in commercial bifacial p-PERC PV modules. Progress in Photovoltaics: Research and Applications 2023; 31(11): 1078–1090.

Rudolph D, Messmer T, Timofte T, et al. Improvement of solder interconnections applied on back contact solar cells with low-temperature copper paste busbars. Solar Energy Materials and Solar Cells 2024; 264: 112603.

Jhou JC, Gaurav A, Lin HT, et al. Bandgap tunable perovskite for Si-based triple junction tandem solar cell: Numerical analysis-aided experimental investigation. Acs Applied Energy Materials 2023; 6(18): 9434–9445.

Wright M, Stefani BV, Jones TW, et al. Design considerations for the bottom cell in perovskite/silicon tandems: A terawatt scalability perspective. Energy and Environmental Science 2023; 16(10): 4164–4190.

Xu ZJ, Bristow H, Babics M, et al. Reverse-bias resilience of monolithic perovskite/silicon tandem solar cells. Joule 2023; 7(9): 1992–2002.

Jang J, Kim JH, Lee S, et al. Efficient flexible organic solar cells with a low-temperature-processed Al-doped zinc oxide electron transport layer. Acs Applied Energy Materials 2023; 6(18): 9778–9787.

Khandelwal K, Shankar SS, Malhotra P, et al. Unraveling the Impact of thickness on active layer morphology and device performance of semitransparent organic solar cells: A comprehensive study. Acs Applied Energy Materials 2023; 6(19): 10078–10087.

Kumagai N, Shimizu T, Minoda H, et al. Visualization of tens of nanometers spaced donor: Acceptor bulk heterojunctions across submicrometer-square cross sections of organic photovoltaic cells. Acs Applied Energy Materials 2023; 6(18): 9363–9370.

Wang J, Zhang CF, Lin Y, et al. Improving performance of organic photovoltaic devices under low illuminations. Acs Applied Energy Materials 2023; 6(19): 10163–10171.

Zhang FH, Yan YJ, Li MD, et al. Efficient ternary indoor organic photovoltaics with fullerene derivative as the host acceptor and nonfullerene material as the guest acceptor. Acs Applied Energy Materials 2023; 6(19): 10137–10146.

Chen QL, Huang H, Ran GL, et al. Improving the performance of layer-by-layer organic solar cells by n-doping of the acceptor layer. Acs Applied Materials and Interfaces 2023; 15(39): 46138–46147.

Sun FB, Wang XC, Wan M, et al. High miscibility-induced reduction of trap density in all-polymer solar cells using hybrid cyclohexyl-hexyl side chains. Advanced Functional Materials 2023; 33: 2306791.

Guo CH, Fu YW, Li DH, et al. A polycrystalline polymer donor as pre-aggregate toward ordered molecular aggregation for 19.3% efficiency binary organic solar cells. Advanced Materials 2023; 35: 2304921.

Cui Y, Zhao C, Souza JPA, et al. Eliminating the imbalanced mobility bottlenecks via reshaping internal potential distribution in organic photovoltaics. Advanced Science 2023; 10(29): 2302880.

Li H, Gao T, He DX, et al. Flashing ratchet effect for driving carriers to accelerate directional migration in organic photovoltaic devices. Applied Physics Letters 2023; 123(10): 103902.

Lewinska G, Kanak J, Danel KS, et al. Effect of benzene-based dyes on optothermal properties of active layers for ternary organic solar cells. Applied Surface Science 2023; 641: 158535.

Kong XY, Zhan LL, Li SX, et al. Spontaneous vertical phase distribution of multi-acceptors system enables high-efficiency organic photovoltaics in non-halogenated solvent and large-area module application. Chemical Engineering Journal 2023; 473: 145201.

Li MY, Wu HB, Wang J, et al. Reducing voltage losses in organic solar cells based on fluorinated acceptors. Chemical Engineering Journal 2023; 474: 145390.

Wang HQ, Yang DB, Ding PF, et al. Dual Forster resonance energy transfer effects enables high photocurrent density and high fill factor in ternary organic solar cells. Chemical Engineering Journal 2023; 474: 145395.

Smeets S, Liu Q, Vanderspikken J, et al. Structurally pure and reproducible polymer materials for high-performance organic solar cells. Chemistry of Materials 2023; 35(19): 8158–8169.

Siddika S, Peng ZX, Balar N, et al. Molecular interactions that drive morphological and mechanical stabilities in organic solar cells. Joule 2023; 7(7): 1593–1608.

Kim W, Oh J, Park J, et al. Building-up relations between intra- and intermolecular interactions, miscibility, and performance for low-cost, efficient fully non-fused acceptor-based organic solar cells. Nano Energy 2023; 117: 108853.

Jiang YY, Li YX, Liu F, et al. Suppressing electron–phonon coupling in organic photovoltaics for high-efficiency power conversion. Nature Communications 2023; 14(1): 5079.

Wang YM, Gao F. Mechanisms for improved open-circuit voltage in ternary organic solar cells. Nature Energy 2023; 8(9): 919–920.

Tan H, Fan WX, Zhu MB, et al. Nonfused ring electron acceptors for ternary polymer solar cells with low energy loss and efficiency over 18%. Small 2023; 2304368.

Zhou HR, Lee HJ, Masud M, et al. Synergistic effect of size-tailored structural engineering and postinterface modification for highly efficient and stable dye-sensitized solar cells. Acs Applied Materials and Interfaces 2023; 15(37): 43835–43844.

Speranza R, Zaccagnini P, Scalia A, et al. Pouch-sealing as an effective way to fabricate flexible dye-sensitized solar cells and their integration with supercapacitors. Journal of Power Sources 2023; 583: 233581.

Yoo K, Kaliamurthy AK, Lee JJ, et al. PVP/PEG polymer blend based electrolytes for quasi-solid-state dye-sensitized solar cells operating at low temperature. Journal of Power Sources 2023; 583: 233568.

Alizadeh A, Roudgar-Amoli M, Shariatinia Z, et al. Recent developments of perovskites oxides and spinel materials as platinum-free counter electrodes for dye-sensitized solar cells: A comprehensive review. Renewable and Sustainable Energy Reviews 2023; 187: 113770.

Gianola G, Speranza R, Bella F, et al. Homo-tandem-bifacial dye-sensitized solar cell: A new paradigm to boost photoconversion efficiency above limit. Solar Energy 2023; 265: 112116.

Scarano V, Gontrani L, Zarate AYS, et al. A new push–pull dye for semi-transparent p-type dye-sensitized solar cells: Tuning conjugation by sexithiophene chain engineering. Solar Energy 2023; 265: 112143.

Chen JW, Wu C, Wang MH, et al. Involving hydroxyl-rich D-glucamine to address hole extraction interfacial issues toward efficient and stable tin-based perovskite solar cells. Acs Applied Energy Materials 2023; 6(19): 9815–9823.

Magliano E, Mariani P, Agresti A, et al. Semitransparent perovskite solar cells with ultrathin protective buffer layers. Acs Applied Energy Materials 2023; 6(20): 10340–10353.

Majhi T, Sridevi M, Jain S, et al. Insight into controlled surface passivation of PEDOT:PSS for defect density modulation and efficient charge transport for perovskite solar cells. Acs Applied Energy Materials 2023; 6(17): 8695–8706.

Zhang K, Feng Y, Tang HR, et al. Stable and efficient inverted perovskite solar cells enabled by structural design of lewis base molecules. Acs Applied Energy Materials 2023; 6(18): 9276–9286.

Zou YH, Lin CH, Hu HH, et al. Multifunctional interface treatment of phosphate for high-efficiency perovskite solar cells. Acs Applied Energy Materials 2023; 6(19): 9994–10004.

Coffey AH, Yang SJ, Gómez M, et al. Controlling crystallization of quasi-2D perovskite solar cells: Incorporating bulky conjugated ligands. Advanced Energy Materials 2023; 13(33): 2201501.

Huddy JE, Scheideler WJ. Rapid 2D Patterning of high-performance perovskites using large area flexography. Advanced Functional Materials 2023; 2306312.

Sadeghi I, Van Sambeek J, Simonian T, et al. Expanding the perovskite periodic table to include chalcogenide alloys with tunable band gap spanning 1.5–1.9 eV. Advanced Functional Materials 2023; 2304575.

Guo J, Meng G, Zhang X, et al. Dual-interface modulation with covalent organic framework enables efficient and durable perovskite solar cells. Advanced Materials 2023; 35(38): 2302839.

Yue W, Yang H, Cai H, et al. Printable high-efficiency and stable FAPbBr3 perovskite solar cells for multifunctional building-integrated photovoltaics. Advanced Materials 2023; 35(36): 2301548.

Huang D, Wang K, Li ZN, et al. A machine learning prediction model for quantitative analyzing the influence of non-radiative voltage loss on non-fullerene organic solar cells. Chemical Engineering Journal 2023; 475: 119–127.

Wan L, Lou LY, Wang ZS. The synergistic strategy of hexaazatrinaphthylene-cyanoindone-based electron transporting material enabling efficient and stable inverted perovskite solar cells. Chemical Engineering Journal 2023; 474: 145808.

Yin X, Wang ZY, Zhao YJ, et al. Cross-linking polymerization boosts the performance of perovskite solar cells: From material design to performance regulation. Energy and Environmental Science 2023; 16(10): 4251–4279.

Du T, Qiu SD, Zhou X, et al. Efficient, stable, and fully printed carbon-electrode perovskite solar cells enabled by hole-transporting bilayers. Joule 2023; 7(8): 1920–1937.

Li GP, Qin F, Jacobberger RM, et al. What is the role of non-fullerene acceptor symmetry in polymer solar cell efficiency? Joule 2023; 7(9): 2152–2173.

Li T, He F, Liang J, et al. Functional layers in efficient and stable inverted tin-based perovskite solar cells. Joule 2023; 7(9): 1966–1991.

Wang JD, Dong Z, Wang JJ, et al. Room-temperature processed TiO2 to construct composite electron transport layers for efficient planar perovskite solar cells. Journal of Materials Chemistry A 2023; 11(41): 22206–22215.

Hidalgo J, Atourki L, Li RP, et al. Bulky cation hinders undesired secondary phases in FAPbI3 perovskite solar cells. Materials Today 2023; 68: 13–21.

Shin S, Shin H. Aging of perovskite solar cells: A mini review. Materials Today Energy 2023; 37: 101381.

Cheng CD, Yao YG, Li L, et al. A novel organic phosphonate additive induced stable and efficient perovskite solar cells with efficiency over 24% enabled by synergetic crystallization promotion and defect passivation. Nano Letters 2023; 23(19): 8850–8859.

Luo YJ, Liu KK, Yang L, et al. Dissolved-Cl2 triggered redox reaction enables high-performance perovskite solar cells. Nature Communications 2023; 14(1): 3738.

Zhou J, Liu Z, Yu P, et al. Modulation of perovskite degradation with multiple-barrier for light-heat stable perovskite solar cells. Nature Communications 2023; 14(1): 6120.

Li GX, Su ZH, Canil L, et al. Highly efficient p-i-n perovskite solar cells that endure temperature variations. Science 2023; 379(6630): 399–403.

Park SM, Wei MY, Xu J, et al. Engineering ligand reactivity enables high-temperature operation of stable perovskite solar cells. Science 2023; 381(6654): 209–215.

Mandal TN, Heo JH, Im SH, et al. Highly efficient and stable inverted perovskite solar cell using pure d-FAPbI3 single crystals. Small 2023; 2305246.

Narayanan V, Rajni KS. CdTe Photovoltaics in superstrate geometry-back-contact materials: A review. Acs Applied Energy Materials 2023; 6(17): 8644–8659.

Wang MY, Geng H, Zhu JC, et al. Hyperactive selenium source yields kesterite solar cells with 12.86% efficiency. Advanced Functional Materials 2023; 2307389.

Gehrke AS, Sommer DE, Dunham ST. Atomistic models of In and Ga diffusion in Cu(In,Ga)Se2. Journal of Applied Physics 2023; 134(11): 115002.

Dong LZ, Tao SY, Zhao M, et al. Crystallization mechanism and defect passivation of Cu2ZnSn(S,Se)4 thin film solar cells via in situ potassium doping. Journal of Materials Chemistry A 2023; 11(37): 20139–20150.

Hwang J, Park H, Shin D, et al. Reforming material chemistry of CIGS solar cells via a precise Ag doping strategy. Journal of Materials Chemistry A 2023; 11(36): 19546–19555.

Liu JL, Cai H, Wu XY, et al. Interface-suppressed high-quality symmetrical bifacial flexible CZTSe solar cells through a green electrodeposition process. Journal of Materials Chemistry A 2023; 11(39): 21293–21299.

Khattak YH, Baig F, Bouich A, et al. Designing next-generation kesterite solar cells: A systematic numerical investigation of innovative structures and design variants for enhanced photovoltaic performance. Solar Energy 2023; 265: 112105.

Sawa HB, Babucci M, Donzel-Gargand O, et al. Enhanced performance of Cu2ZnSnS4 based bifacial solar cells with FTO and W/FTO back contacts through absorber air annealing and Na incorporation. Solar Energy Materials and Solar Cells 2024; 264: 112605.

Stam M, du Fossé I, Infante I, et al. Guilty as charged: The role of undercoordinated indium in electron-charged indium phosphide quantum dots. Acs Nano 2023; 17(18): 18576–18583.

Zhao B, Guo JJ, Zhao CY, et al. Design and synthesis of fluorinated quantum dots for efficient and stable 0D/3D perovskite solar cells. Advanced Functional Materials 2023; 33: 2304161.

Wang DY, Zou WH, Chen YX, et al. Enhanced photovoltaic performance of CdSe quantum dot-sensitized solar cells with Eu-doped TiO2 photoanode. Applied Physics a-Materials Science and Processing 2023; 129(11): 752.

Sun Z, Hou QG, Zhang RL, et al. Facile surface pseudohalide pretreatment of quantum dots for efficient photovoltaics. Chemical Engineering Journal 2023; 474: 145657.

Salah FEA, Maouhoub N, Tifidat K, et al. An efficient analytical approach for forecasting the peak power of PV panels working in outdoor conditions based on explicit model. Energy Conversion and Management: X 2023; 20: 100423.

Abedi S, Moradi MH, Shirmohammadi R. Real-time photovoltaic energy assessment using a GSM-based smart monitoring system: Addressing the impact of climate change on solar energy estimation software. Energy Reports 2023; 10: 2361–2373.

Chang CCW, Ding TJ, Han W, et al. Moth flame optimization for the maximum power point tracking scheme of photovoltaic system under partial shading conditions. Energy Reports 2023; 9: 374–379.

Dbouk HM, Chehimi M, Khalaf A. Photovoltaic sizing using machine learning. Energy Reports 2023; 9: 512–518.

Sahin G, Isik G, van Sark W. Predictive modeling of PV solar power plant efficiency considering weather conditions: A comparative analysis of artificial neural networks and multiple linear regression. Energy Reports 2023; 10: 2837–2849.

Sharma A, Lim WH, El-Kenawy EM, et al. Identification of photovoltaic module parameters by implementing a novel teaching learning based optimization with unique exemplar generation scheme (TLBO-UEGS). Energy Reports 2023; 10: 1485–1506.

Singh S, Powar S. Putting into practice a decision-making framework for a thorough performance and location evaluation of solar photovoltaic plants in India from distinctive climate zones. Energy Strategy Reviews 2023; 50: 101202.

Al-Wesabi I, Fang ZJ, Farh HMH, et al. Dynamic global power extraction of partially shaded PV system using a hybrid MPSO-PID with anti-windup strategy. Engineering Applications of Artificial Intelligence 2023; 126: 106965.

Wang LC, Xie LC, Yang Y, et al. Distributed online voltage control with fast PV power fluctuations and imperfect communication. IEEE Transactions on Smart Grid 2023; 14(5): 3681–3695.

Tripathi S, Chopra S, Sahu HS, et al. A novel MPP estimation technique for DDM PV array under different solar irradiance conditions. IEEE Transactions on Sustainable Energy 2023; 14(4): 2177–2191.

Hu S, Wu ZR, Li SS, et al. Research on dust deposition of PV modules based on three-dimensional numerical simulation and its application in installation parameter optimization. Journal of Cleaner Production 2023; 423: 138743.

Ali Khan Niazi K, Victoria M. Comparative analysis of photovoltaic configurations for agrivoltaic systems in Europe. Progress in Photovoltaics: Research and Applications 2023; 31(11): 1101–1113.

Merodio P, Martínez-Moreno F, Moretón R, et al. Albedo measurements and energy yield estimation uncertainty for bifacial photovoltaic systems. Progress in Photovoltaics: Research and Applications 2023; 31(11): 1130–1143.

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来源期刊
Progress in Photovoltaics
Progress in Photovoltaics 工程技术-能源与燃料
CiteScore
18.10
自引率
7.50%
发文量
130
审稿时长
5.4 months
期刊介绍: Progress in Photovoltaics offers a prestigious forum for reporting advances in this rapidly developing technology, aiming to reach all interested professionals, researchers and energy policy-makers. The key criterion is that all papers submitted should report substantial “progress” in photovoltaics. Papers are encouraged that report substantial “progress” such as gains in independently certified solar cell efficiency, eligible for a new entry in the journal''s widely referenced Solar Cell Efficiency Tables. Examples of papers that will not be considered for publication are those that report development in materials without relation to data on cell performance, routine analysis, characterisation or modelling of cells or processing sequences, routine reports of system performance, improvements in electronic hardware design, or country programs, although invited papers may occasionally be solicited in these areas to capture accumulated “progress”.
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