Photovoltaics Literature Survey (No. 194)

IF 8 2区 材料科学 Q1 ENERGY & FUELS Progress in Photovoltaics Pub Date : 2024-11-11 DOI:10.1002/pip.3857
Ziv Hameiri
{"title":"Photovoltaics Literature Survey (No. 194)","authors":"Ziv Hameiri","doi":"10.1002/pip.3857","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>Wang B, Chen Q, Wang MM, et al. <b>PVF-10: A high-resolution unmanned aerial vehicle thermal infrared image dataset for fine-grained photovoltaic fault classification.</b> <i>Applied Energy</i> 2024; <b>376</b>: 124187.</p><p>Ozturk E, Ogliari E, Sakwa M, et al. <b>Photovoltaic modules fault detection, power output, and parameter estimation: A deep learning approach based on electroluminescence images.</b> <i>Energy Conversion and Management</i> 2024; <b>319</b>: 118866.</p><p>Almora O, Lopez-Varo P, Escalante R, et al. <b>Instability analysis of perovskite solar cells via short-circuit impedance spectroscopy: A case study on NiO</b><sub><b>x</b></sub> <b>passivation.</b> <i>Journal of Applied Physics</i> 2024; <b>136</b>(9): 094502.</p><p>El Khoury M, Moret M, Tiberj A, et al. <b>Determination of light-independent shunt resistance in CIGS photovoltaic cells using a collection function-based model.</b> <i>Journal of Applied Physics</i> 2024; <b>136</b>(2): 024502.</p><p>Li JC, Ji Q, Wang R, et al. <b>Charge generation dynamics in organic photovoltaic blends under one-sun-equivalent illumination detected by highly sensitive terahertz spectroscopy.</b> <i>Journal of the American Chemical Society</i> 2024; <b>146</b>(29): 20312-20322.</p><p>Sandner D, Sun K, Stadlbauer A, et al. <b>Hole localization in bulk and 2D lead-halide perovskites studied by time-resolved infrared spectroscopy.</b> <i>Journal of the American Chemical Society</i> 2024; <b>146</b>(29): 19852-19862.</p><p>Li Y, Wright B, Hameiri Z. <b>Deep learning-based perspective distortion correction for outdoor photovoltaic module images.</b> <i>Solar Energy Materials and Solar Cells</i> 2024; <b>277</b>: 113107.</p><p>Wang S, Wright B, Zhu Y, et al. <b>Extracting the parameters of two-energy-level defects in silicon wafers using machine learning models.</b> <i>Solar Energy Materials and Solar Cells</i> 2024; <b>277</b>: 113123.</p><p>Zhou YN, Zhang HH, Li ZF, et al. <b>Heavy boron-doped silicon tunneling inter-layer enables efficient silicon heterojunction solar cells.</b> <i>Acs Applied Materials and Interfaces</i> 2024; <b>16</b>(35): 46889-46896.</p><p>Li WK, Zhou R, Wang YK, et al. <b>Preparation of Al</b><sub><b>2</b></sub><b>O</b><sub><b>3</b></sub> <b>thin films by RS-ALD and edge passivation application for TOPCon half solar cells.</b> <i>Applied Surface Science</i> 2024; <b>673</b>: 160835.</p><p>Su H, Dou C, Dou F, et al. <b>Enhanced photovoltaic performance of silicon solar cells using a down-shift KCa</b><sub><b>2</b></sub><b>Mg</b><sub><b>2</b></sub><b>(VO</b><sub><b>4</b></sub><b>)</b><sub><b>3</b></sub> <b>phosphor.</b> <i>Dalton Transactions</i> 2024; <b>53</b>(35): 14648-14655.</p><p>Wöhler W, Greulich J. <b>Light trapping in silicon solar cells including secondary reflection on the surrounding.</b> <i>IEEE Journal of Photovoltaics</i> 2024; <b>14</b>(5): 737-744.</p><p>Ide K, Nishihara T, Nakamura K, et al. <b>Evaluation of the effect of texture size and rounding process on three-dimensional flexibility of c-Si wafer.</b> <i>Japanese Journal of Applied Physics</i> 2024; <b>63</b>(8): 085503.</p><p>Ziar H. <b>A global statistical assessment of designing silicon-based solar cells for geographical markets.</b> <i>Joule</i> 2024; <b>8</b>(6): 1667-1690.</p><p>Li Y, Ru XN, Yang M, et al. <b>Flexible silicon solar cells with high power-to-weight ratios.</b> <i>Nature</i> 2024; <b>626</b>(7997): 105–110.</p><p>Lorenz A, Wenzel T, Pingel S, et al. <b>Towards a cutting-edge metallization process for silicon heterojunction solar cells with very low silver laydown.</b> <i>Progress in Photovoltaics: Research and Applications</i> 2024; <b>32</b>(10): 655-663.</p><p>Soler-Castillo Y, Sahni M, Leon-Castro E. <b>The dynamic of photovoltaic resources on its performance predictability, based on two new approaches.</b> <i>Progress in Photovoltaics: Research and Applications</i> 2024; <b>32</b>(10): 701-745.</p><p>Xie A, Wang G, Sun Y, et al. <b>Bifacial silicon heterojunction solar cells using transparent-conductive-oxide- and dopant-free electron-selective contacts.</b> <i>Progress in Photovoltaics: Research and Applications</i> 2024; <b>32</b>(10): 664-674.</p><p>Ding D, Gao C, Wang X, et al. <b>Optimization of rear surface morphology in n-type TOPCon c-Si solar cells.</b> <i>Solar Energy Materials and Solar Cells</i> 2024; <b>277</b>: 113142.</p><p>Jiang XL, Chen XY, Zhang JB, et al. <b>Phosphorus doped hydrogenated silicon oxycarbide: Film formation, properties and its application on silicon heterojunction solar cell.</b> <i>Solar Energy Materials and Solar Cells</i> 2024; <b>277</b>: 113103.</p><p>Kashizadeh A, Basnet R, Black L, et al. <b>Auger-limited bulk lifetimes in industrial Czochralski-grown n-type silicon ingots with melt recharging.</b> <i>Solar Energy Materials and Solar Cells</i> 2024; <b>277</b>: 113143.</p><p>Mette A, Hörnlein S, Stenzel F, et al. <b>Q.ANTUM NEO with LECO Exceeding 25.5% cell Efficiency.</b> <i>Solar Energy Materials and Solar Cells</i> 2024; <b>277</b>: 113110.</p><p>Qin X, Chen W, Sun F, et al. <b>Enhanced adhesion strength of copper metallization on silicon heterojunction solar cell due to improved electrochemical reduction uniformity of ITO.</b> <i>Solar Energy Materials and Solar Cells</i> 2024; <b>277</b>: 113132.</p><p>Wan W, Shi J, Liang Y, et al. <b>Optimizing phosphorus-doped polysilicon in TOPCon structures using silicon oxide layers to improve silicon solar cell performance.</b> <i>Solar Energy Materials and Solar Cells</i> 2024; <b>276</b>: 113068.</p><p>Xing M, Wang T, Cao F, et al. <b>Advancing nickel seed layer electroplating for enhanced contact and passivation performance in TOPCon solar cells.</b> <i>Solar Energy Materials and Solar Cells</i> 2024; <b>277</b>: 113108.</p><p>Yang J, Tang Y, Zhou C, et al. <b>Unveiling the mechanism of ultraviolet-induced degradation in silicon heterojunction solar cells.</b> <i>Solar Energy Materials and Solar Cells</i> 2024; <b>276</b>: 113062.</p><p>Yousuf H, Khokhar MQ, Alamgeer, et al. <b>Improving n-TOPCon solar cell printing conditions and performance analysis by local dot contact approaches.</b> <i>Solar Energy Materials and Solar Cells</i> 2024; <b>277</b>: 113139.</p><p>Zhou R, Li YS, Tan WC, et al. <b>Insight of effect of silver powders on silver-silicon contacts of crystalline silicon solar cells through analysis of glass structural decay.</b> <i>Solar RRL</i> 2024; <b>8</b>(14): 2400299.</p><p>Qiang ZY, Wu Y, Gao X, et al. <b>A scalable method for fabricating monolithic perovskite/silicon tandem solar cells based on low-cost industrial silicon bottom cells.</b> <i>Chemical Engineering Journal</i> 2024; <b>495</b>: 153422.</p><p>Song TF, Jeswani HK, Azapagic A. <b>Assessing the environmental and economic sustainability of emerging tandem photovoltaic technologies in China.</b> <i>Energy Conversion and Management</i> 2024; <b>318</b>: 118890.</p><p>Fu S, Sun NN, Xian YM, et al. <b>Suppressed deprotonation enables a durable buried interface in tin-lead perovskite for all-perovskite tandem solar cells.</b> <i>Joule</i> 2024; <b>8</b>(8): 2220-2237.</p><p>Turkay D, Artuk K, Chin XY, et al. <b>Synergetic substrate and additive engineering for over 30%-efficient perovskite-Si tandem solar cells.</b> <i>Joule</i> 2024; <b>8</b>(6): 1735-1753.</p><p>Duan LP, Phang SP, Yan D, et al. <b>Over 29%-efficient, stable n-i-p monolithic perovskite/silicon tandem solar cells based on double-sided poly-Si/SiO</b><sub><b>2</b></sub> <b>passivating contact silicon cells.</b> <i>Journal of Materials Chemistry A</i> 2024; <b>12</b>(31): 20006-20016.</p><p>Gao C, Zhang H, Ma S, et al. <b>Quasi-conformal monolithic n-i-p perovskite/c-Si tandem solar cells with light management strategies exceed 28 % efficiency.</b> <i>Nano Energy</i> 2024; <b>129</b>: 110066.</p><p>Hou FH, Ren XQ, Guo HK, et al. <b>Monolithic perovskite/silicon tandem solar cells: A review of the present status and solutions toward commercial application.</b> <i>Nano Energy</i> 2024; <b>124</b>: 109476.</p><p>Li JX, Farhadi B, Liu SY, et al. <b>Built-in field manipulation through a perovskite homojunction for efficient monolithic perovskite/silicon tandem solar cells.</b> <i>Nano Energy</i> 2024; <b>129</b>: 109976.</p><p>Pei FT, Chen YH, Wang QQ, et al. <b>A binary 2D perovskite passivation for efficient and stable perovskite/silicon tandem solar cells.</b> <i>Nature Communications</i> 2024; <b>15</b>(1): 7024.</p><p>Aydin E, Allen TG, De Bastiani M, et al. <b>Pathways toward commercial perovskite/silicon tandem photovoltaics.</b> <i>Science</i> 2024; <b>383</b>(6679): 162.</p><p>Chen YH, Yang N, Zheng GHJ, et al. <b>Nuclei engineering for even halide distribution in stable perovskite/silicon tandem solar cells.</b> <i>Science</i> 2024; <b>385</b>(6708): 554-560.</p><p>Ugur E, Said AA, Dally P, et al. <b>Enhanced cation interaction in perovskites for efficient tandem solar cells with silicon.</b> <i>Science</i> 2024; <b>385</b>(6708): 533-538.</p><p>Chang B, Jiang BH, Chen CP, et al. <b>Achieving high efficiency and stability in organic photovoltaics with a nanometer-scale twin p-i-n structured active layer.</b> <i>Acs Applied Materials and Interfaces</i> 2024; <b>16</b>(31): 41244-41256.</p><p>Jeong S, Oh J, Park J, et al. <b>Visible-transparent electron-selective self-assembled monolayer for electron-transport-layer-free high-efficiency and flexible organic solar cells.</b> <i>Acs Energy Letters</i> 2024; <b>9</b>(8): 3771-3779.</p><p>Zhang Z, Yuan SH, Chen TQ, et al. <b>Rational design of flexible-linked 3D dimeric acceptors for stable organic solar cells demonstrating 19.2% efficiency.</b> <i>Energy and Environmental Science</i> 2024; <b>17</b>(15): 5719-5729.</p><p>Zhao ZM, Chung S, Kim YY, et al. <b>Room-temperature-modulated polymorphism of nonfullerene acceptors enables efficient bilayer organic solar cells.</b> <i>Energy and Environmental Science</i> 2024; <b>17</b>(15): 5666-5678.</p><p>Cheng JC, Guo CH, Wang L, et al. <b>Device engineering of non-fullerene organic photovoltaics with extrapolated operational T</b><sub><b>80</b></sub> <b>lifetime over 45,000 h in air.</b> <i>Joule</i> 2024; <b>8</b>(8): 2250-2264.</p><p>Tang H, Liao ZH, Chen QQ, et al. <b>Elucidating the optimal material combinations of organic photovoltaics for maximum industrial viability.</b> <i>Joule</i> 2024; <b>8</b>(8): 2208-2219.</p><p>Valente GT, Guimaraes FEG. <b>Probabilistic modeling of energy transfer in disordered organic semiconductors.</b> <i>Journal of Applied Physics</i> 2024; <b>136</b>(8): 084501.</p><p>Zhou X, Gu CT, Zheng CY, et al. <b>Cost-effective polymer donors with simple structure for organic solar cells.</b> <i>Journal of Materials Chemistry A</i> 2024; <b>12</b>(31): 19839-19860.</p><p>Li HJ, Liu SQ, Liu H, et al. <b>Dynamics parameter correction for predicting the long-term stability of organic photovoltaics.</b> <i>Macromolecules</i> 2024; <b>57</b>(14): 6548-6558.</p><p>Cao LY, Zhang HY, Du XY, et al. <b>Highly electronegative additives suppress energetic disorder to realize 19.19% efficiency binary organic solar cells.</b> <i>Nano Energy</i> 2024; <b>129</b>: 110016.</p><p>Hou H, Wang WX, Kang Q, et al. <b>Undoped MoO</b><sub><b>X</b></sub> <b>with oxygen-rich vacancies as hole transport material for efficient indoor/outdoor organic solar cells.</b> <i>Nano Energy</i> 2024; 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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].

Wang B, Chen Q, Wang MM, et al. PVF-10: A high-resolution unmanned aerial vehicle thermal infrared image dataset for fine-grained photovoltaic fault classification. Applied Energy 2024; 376: 124187.

Ozturk E, Ogliari E, Sakwa M, et al. Photovoltaic modules fault detection, power output, and parameter estimation: A deep learning approach based on electroluminescence images. Energy Conversion and Management 2024; 319: 118866.

Almora O, Lopez-Varo P, Escalante R, et al. Instability analysis of perovskite solar cells via short-circuit impedance spectroscopy: A case study on NiOx passivation. Journal of Applied Physics 2024; 136(9): 094502.

El Khoury M, Moret M, Tiberj A, et al. Determination of light-independent shunt resistance in CIGS photovoltaic cells using a collection function-based model. Journal of Applied Physics 2024; 136(2): 024502.

Li JC, Ji Q, Wang R, et al. Charge generation dynamics in organic photovoltaic blends under one-sun-equivalent illumination detected by highly sensitive terahertz spectroscopy. Journal of the American Chemical Society 2024; 146(29): 20312-20322.

Sandner D, Sun K, Stadlbauer A, et al. Hole localization in bulk and 2D lead-halide perovskites studied by time-resolved infrared spectroscopy. Journal of the American Chemical Society 2024; 146(29): 19852-19862.

Li Y, Wright B, Hameiri Z. Deep learning-based perspective distortion correction for outdoor photovoltaic module images. Solar Energy Materials and Solar Cells 2024; 277: 113107.

Wang S, Wright B, Zhu Y, et al. Extracting the parameters of two-energy-level defects in silicon wafers using machine learning models. Solar Energy Materials and Solar Cells 2024; 277: 113123.

Zhou YN, Zhang HH, Li ZF, et al. Heavy boron-doped silicon tunneling inter-layer enables efficient silicon heterojunction solar cells. Acs Applied Materials and Interfaces 2024; 16(35): 46889-46896.

Li WK, Zhou R, Wang YK, et al. Preparation of Al2O3 thin films by RS-ALD and edge passivation application for TOPCon half solar cells. Applied Surface Science 2024; 673: 160835.

Su H, Dou C, Dou F, et al. Enhanced photovoltaic performance of silicon solar cells using a down-shift KCa2Mg2(VO4)3 phosphor. Dalton Transactions 2024; 53(35): 14648-14655.

Wöhler W, Greulich J. Light trapping in silicon solar cells including secondary reflection on the surrounding. IEEE Journal of Photovoltaics 2024; 14(5): 737-744.

Ide K, Nishihara T, Nakamura K, et al. Evaluation of the effect of texture size and rounding process on three-dimensional flexibility of c-Si wafer. Japanese Journal of Applied Physics 2024; 63(8): 085503.

Ziar H. A global statistical assessment of designing silicon-based solar cells for geographical markets. Joule 2024; 8(6): 1667-1690.

Li Y, Ru XN, Yang M, et al. Flexible silicon solar cells with high power-to-weight ratios. Nature 2024; 626(7997): 105–110.

Lorenz A, Wenzel T, Pingel S, et al. Towards a cutting-edge metallization process for silicon heterojunction solar cells with very low silver laydown. Progress in Photovoltaics: Research and Applications 2024; 32(10): 655-663.

Soler-Castillo Y, Sahni M, Leon-Castro E. The dynamic of photovoltaic resources on its performance predictability, based on two new approaches. Progress in Photovoltaics: Research and Applications 2024; 32(10): 701-745.

Xie A, Wang G, Sun Y, et al. Bifacial silicon heterojunction solar cells using transparent-conductive-oxide- and dopant-free electron-selective contacts. Progress in Photovoltaics: Research and Applications 2024; 32(10): 664-674.

Ding D, Gao C, Wang X, et al. Optimization of rear surface morphology in n-type TOPCon c-Si solar cells. Solar Energy Materials and Solar Cells 2024; 277: 113142.

Jiang XL, Chen XY, Zhang JB, et al. Phosphorus doped hydrogenated silicon oxycarbide: Film formation, properties and its application on silicon heterojunction solar cell. Solar Energy Materials and Solar Cells 2024; 277: 113103.

Kashizadeh A, Basnet R, Black L, et al. Auger-limited bulk lifetimes in industrial Czochralski-grown n-type silicon ingots with melt recharging. Solar Energy Materials and Solar Cells 2024; 277: 113143.

Mette A, Hörnlein S, Stenzel F, et al. Q.ANTUM NEO with LECO Exceeding 25.5% cell Efficiency. Solar Energy Materials and Solar Cells 2024; 277: 113110.

Qin X, Chen W, Sun F, et al. Enhanced adhesion strength of copper metallization on silicon heterojunction solar cell due to improved electrochemical reduction uniformity of ITO. Solar Energy Materials and Solar Cells 2024; 277: 113132.

Wan W, Shi J, Liang Y, et al. Optimizing phosphorus-doped polysilicon in TOPCon structures using silicon oxide layers to improve silicon solar cell performance. Solar Energy Materials and Solar Cells 2024; 276: 113068.

Xing M, Wang T, Cao F, et al. Advancing nickel seed layer electroplating for enhanced contact and passivation performance in TOPCon solar cells. Solar Energy Materials and Solar Cells 2024; 277: 113108.

Yang J, Tang Y, Zhou C, et al. Unveiling the mechanism of ultraviolet-induced degradation in silicon heterojunction solar cells. Solar Energy Materials and Solar Cells 2024; 276: 113062.

Yousuf H, Khokhar MQ, Alamgeer, et al. Improving n-TOPCon solar cell printing conditions and performance analysis by local dot contact approaches. Solar Energy Materials and Solar Cells 2024; 277: 113139.

Zhou R, Li YS, Tan WC, et al. Insight of effect of silver powders on silver-silicon contacts of crystalline silicon solar cells through analysis of glass structural decay. Solar RRL 2024; 8(14): 2400299.

Qiang ZY, Wu Y, Gao X, et al. A scalable method for fabricating monolithic perovskite/silicon tandem solar cells based on low-cost industrial silicon bottom cells. Chemical Engineering Journal 2024; 495: 153422.

Song TF, Jeswani HK, Azapagic A. Assessing the environmental and economic sustainability of emerging tandem photovoltaic technologies in China. Energy Conversion and Management 2024; 318: 118890.

Fu S, Sun NN, Xian YM, et al. Suppressed deprotonation enables a durable buried interface in tin-lead perovskite for all-perovskite tandem solar cells. Joule 2024; 8(8): 2220-2237.

Turkay D, Artuk K, Chin XY, et al. Synergetic substrate and additive engineering for over 30%-efficient perovskite-Si tandem solar cells. Joule 2024; 8(6): 1735-1753.

Duan LP, Phang SP, Yan D, et al. Over 29%-efficient, stable n-i-p monolithic perovskite/silicon tandem solar cells based on double-sided poly-Si/SiO2 passivating contact silicon cells. Journal of Materials Chemistry A 2024; 12(31): 20006-20016.

Gao C, Zhang H, Ma S, et al. Quasi-conformal monolithic n-i-p perovskite/c-Si tandem solar cells with light management strategies exceed 28 % efficiency. Nano Energy 2024; 129: 110066.

Hou FH, Ren XQ, Guo HK, et al. Monolithic perovskite/silicon tandem solar cells: A review of the present status and solutions toward commercial application. Nano Energy 2024; 124: 109476.

Li JX, Farhadi B, Liu SY, et al. Built-in field manipulation through a perovskite homojunction for efficient monolithic perovskite/silicon tandem solar cells. Nano Energy 2024; 129: 109976.

Pei FT, Chen YH, Wang QQ, et al. A binary 2D perovskite passivation for efficient and stable perovskite/silicon tandem solar cells. Nature Communications 2024; 15(1): 7024.

Aydin E, Allen TG, De Bastiani M, et al. Pathways toward commercial perovskite/silicon tandem photovoltaics. Science 2024; 383(6679): 162.

Chen YH, Yang N, Zheng GHJ, et al. Nuclei engineering for even halide distribution in stable perovskite/silicon tandem solar cells. Science 2024; 385(6708): 554-560.

Ugur E, Said AA, Dally P, et al. Enhanced cation interaction in perovskites for efficient tandem solar cells with silicon. Science 2024; 385(6708): 533-538.

Chang B, Jiang BH, Chen CP, et al. Achieving high efficiency and stability in organic photovoltaics with a nanometer-scale twin p-i-n structured active layer. Acs Applied Materials and Interfaces 2024; 16(31): 41244-41256.

Jeong S, Oh J, Park J, et al. Visible-transparent electron-selective self-assembled monolayer for electron-transport-layer-free high-efficiency and flexible organic solar cells. Acs Energy Letters 2024; 9(8): 3771-3779.

Zhang Z, Yuan SH, Chen TQ, et al. Rational design of flexible-linked 3D dimeric acceptors for stable organic solar cells demonstrating 19.2% efficiency. Energy and Environmental Science 2024; 17(15): 5719-5729.

Zhao ZM, Chung S, Kim YY, et al. Room-temperature-modulated polymorphism of nonfullerene acceptors enables efficient bilayer organic solar cells. Energy and Environmental Science 2024; 17(15): 5666-5678.

Cheng JC, Guo CH, Wang L, et al. Device engineering of non-fullerene organic photovoltaics with extrapolated operational T80 lifetime over 45,000 h in air. Joule 2024; 8(8): 2250-2264.

Tang H, Liao ZH, Chen QQ, et al. Elucidating the optimal material combinations of organic photovoltaics for maximum industrial viability. Joule 2024; 8(8): 2208-2219.

Valente GT, Guimaraes FEG. Probabilistic modeling of energy transfer in disordered organic semiconductors. Journal of Applied Physics 2024; 136(8): 084501.

Zhou X, Gu CT, Zheng CY, et al. Cost-effective polymer donors with simple structure for organic solar cells. Journal of Materials Chemistry A 2024; 12(31): 19839-19860.

Li HJ, Liu SQ, Liu H, et al. Dynamics parameter correction for predicting the long-term stability of organic photovoltaics. Macromolecules 2024; 57(14): 6548-6558.

Cao LY, Zhang HY, Du XY, et al. Highly electronegative additives suppress energetic disorder to realize 19.19% efficiency binary organic solar cells. Nano Energy 2024; 129: 110016.

Hou H, Wang WX, Kang Q, et al. Undoped MoOX with oxygen-rich vacancies as hole transport material for efficient indoor/outdoor organic solar cells. Nano Energy 2024; 131: 110173.

Hu T, Zheng X, Xiao C, et al. Composite side chain induced ordered preaggregation in liquid state for high-performance non-halogen solvent processed organic solar cells. Nano Energy 2024; 130: 110172.

Li QD, Liao XL, Yang ZL, et al. The selenium substitution of solvent additive enables efficient polymer solar cells with efficiency of 19.4%. Nano Energy 2024; 129: 110067.

Zhou JP, Guo CH, Wang L, et al. Thiophene structured additives toward enhanced structural order and reduced non-radiative loss for 19.9% efficiency organic solar cells. Nano Energy 2024; 129: 109988.

Chen C, Wang L, Xia WY, et al. Molecular interaction induced dual fibrils towards organic solar cells with certified efficiency over 20%. Nature Communications 2024; 15(1): 6865.

He XJ, Qi F, Zou XH, et al. Selenium substitution for dielectric constant improvement and hole-transfer acceleration in non-fullerene organic solar cells. Nature Communications 2024; 15(1): 2103.

Jungbluth A, Cho E, Privitera A, et al. Limiting factors for charge generation in low-offset fullerene-based organic solar cells. Nature Communications 2024; 15(1): 5488.

Li DY, Lian Q, Du T, et al. Co-adsorbed self-assembled monolayer enables high-performance perovskite and organic solar cells. Nature Communications 2024; 15(1): 7605.

Annabi Milani E, Piralaee M, Raeyani D, et al. High-performance semi-transparent organic solar cells for window applications using MoO3/Ag/MoO3 transparent anodes. Solar Energy Materials and Solar Cells 2024; 276(113066.

Huang XF, Gao YY, Li WP, et al. Efficient and stable Z907-based dye-sensitized solar cells enabled by suppressed charge recombination and photocatalytic activity. Acs Sustainable Chemistry and Engineering 2024; 12(34): 13007-13016.

Yamada R, Nakagawa M, Hirooka S, et al. Physical reservoir computing with visible-light signals using dye-sensitized solar cells. Applied Physics Express 2024; 17(9): 097001.

Agoro MA, Meyer EL. Coating of CoS on hybrid anode electrode with enhance performance in hybrid dye-sensitized solar cells. Electrochimica Acta 2024; 502: 144877.

McAndrews GR, Guo BY, Kaczaral SC, et al. Moisture uptake relaxes stress in metal halide perovskites at the expense of stability. Acs Energy Letters 2024; 9(8): 4153-4161.

Bie T, Li R, Gao X, et al. Halogen-functionalized hole transport materials with strong passivation effects for stable and highly efficient quasi-2D perovskite solar cells. Acs Nano 2024; 18(34): 23615-23624.

Chen JW, Fan X, Wang JZ, et al. 23.81%-efficiency flexible inverted perovskite solar cells with enhanced stability and flexibility via a Lewis base passivation. Acs Nano 2024; 18(29): 19190-19199.

Li RD, Sun ZY, Yao LB, et al. Unraveling the degradation mechanisms of perovskite solar cells under mechanical tensile loads. Acs Nano 2024; 18(35): 24495-24504.

Roe J, Son JG, Park S, et al. Synergistic buried interface regulation of tin-lead perovskite solar cells via co-self-assembled monolayers. Acs Nano 2024; 18(35): 24306-24316.

Tang JW, Lin Y, Yan HC, et al. 20.1% certified efficiency of planar hole transport layer-free carbon-based perovskite solar cells by spacer cation chain length engineering of 2D perovskites. Angewandte Chemie-International Edition 2024; 63(33): e202406167.

Zhou H, Wang WL, Duan YW, et al. Glycol monomethyl ether-substituted carbazolyl hole-transporting material for stable inverted perovskite solar cells with efficiency of 25.52%. Angewandte Chemie-International Edition 2024; 63(33): e202403068.

Ahn S, Chiu WH, Chu WC, et al. A systematic investigation of PVDF-HFP in perovskite solar cells for improved space mission reliability. Chemical Engineering Journal 2024; 496: 153974.

Ma Z, He B, Tui R, et al. Multifunctional molecular bridge enabled interface passivation and strain release for stable and efficient all-inorganic perovskite solar cells. Chemical Engineering Journal 2024; 498: 155396.

Zhang WY, Zhou QS, Qiu JM, et al. Synergistic effects of the physical modification and chemical passivation enabling efficient perovskite solar cells. Chemical Engineering Journal 2024; 497: 154864.

Yi A, Chae S, Luong HM, et al. Room-temperature-processed perovskite solar cells surpassing 24% efficiency. Joule 2024; 8(7): 2087-2104.

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Dai ZY, Yang Y, Huang XF, et al. Interfacial crosslinking benzimidazolium enables eco-friendly inverted perovskite solar cells and modules. Nano Energy 2024; 131: 110190.

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光伏文献调查(第 194 号)
为了帮助读者了解该领域的最新进展,每期《光伏进展》都会列出一份最近发表的与其目标和范围最相关的期刊文章清单。这份清单选自极为广泛的期刊,包括《IEEE 光伏学报》、《太阳能材料和太阳能电池》、《可再生能源》、《可再生和可持续能源评论》、《应用物理学报》和《应用物理快报》。为了帮助读者,本列表分为几大类,但请注意,这些分类并不严格。同时请注意,列入列表并不代表对论文质量的认可。Wang B, Chen Q, Wang MM, et al. PVF-10: A high-resolution unmanned aerial vehicle thermal infrared image dataset for fine-grained photovoltaic fault classification.Ozturk E, Ogliari E, Sakwa M, et al. Photovoltaic modules fault detection, power output, and parameter estimation:基于电致发光图像的深度学习方法。Almora O, Lopez-Varo P, Escalante R, et al:镍氧化物钝化案例研究。应用物理学杂志》,2024 年,136(9):094502.El Khoury M, Moret M, Tiberj A, et al.应用物理学杂志》,2024 年,136(2):024502.Li JC, Ji Q, Wang R, et al.Sandner D, Sun K, Stadlbauer A, et al.美国化学学会学报》,2024 年;146(29):19852-19862.Li Y, Wright B, Hameiri Z.基于深度学习的室外光伏组件图像透视畸变校正太阳能材料与太阳能电池 2024; 277:Wang S, Wright B, Zhu Y, et al.太阳能材料与太阳能电池 2024; 277:Zhou YN, Zhang HH, Li ZF, et al.Acs Applied Materials and Interfaces 2024; 16(35):Li WK, Zhou R, Wang YK, et al.Su H, Dou C, Dou F, et al. Enhanced photovoltaic performance of silicon solar cells using a down-shift KCa2Mg2(VO4)3 phosphor.Dalton Transactions 2024; 53(35):14648-14655.Wöhler W, Greulich J. 硅太阳能电池中的光捕获,包括对周围的二次反射。IEEE 光伏学报 2024; 14(5):Ide K, Nishihara T, Nakamura K, et al. Evaluation of the effect of texture size and rounding process on three-dimensional flexibility of c-Si wafer.日本应用物理学杂志》,2024 年;63(8):085503.Ziar H. 针对地理市场设计硅基太阳能电池的全球统计评估。Joule 2024; 8(6):1667-1690.Li Y, Ru XN, Yang M, et al. Flexible silicon solar cells with high power-to-weight ratios.自然 2024; 626(7997):Lorenz A, Wenzel T, Pingel S, et al. Towards a cutting-edge metallization process for silicon heterojunction solar cells with very low silver laydown.光伏技术进展:研究与应用》,2024 年,第 32(10)期:655-663.Soler-Castillo Y, Sahni M, Leon-Castro E. 基于两种新方法的光伏资源动态性能预测。光伏技术进展:研究与应用》,2024 年,第 32(10)期,第 701-745 页:701-745.Xie A, Wang G, Sun Y, et al. Bifacial silicon heterojunction solar cells using transparent-conductive-oxide- and dopant-free electron-selective contacts.光伏学进展:Photovoltaics: Research and Applications 2024; 32(10):Ding D, Gao C, Wang X, et al.太阳能材料与太阳能电池 2024; 277:Jiang XL, Chen XY, Zhang JB, et al:掺磷氢化碳化硅:薄膜形成、性能及其在硅异质结太阳能电池上的应用。太阳能材料与太阳能电池,2024;277:Kashizadeh A, Basnet R, Black L, et al.太阳能材料和太阳能电池》,2024 年,第 277 期:Mette A, Hörnlein S, Stenzel F, et al.使用 LECO 的 Q.ANTUM NEO 电池效率超过 25.5%。 Dai ZY, Yang Y, Huang XF, et al.Han EQ, Yun JH, Maeng I, et al. Efficient bifacial semi-transparent perovskite solar cells via a dimethylformamide-free solvent and bandgap engineering strategy.He ZY, Zhang SF, Wei QL, et al.Liu QY, Ou ZP, Ma Z, et al. Perovskite solar cells with self-disintegrating seeds deliver an 83.64% fill factor.Nano Energy 2024; 127: 109751.Niu GS, Bai BW, Wang YD, et al:通过纳米石墨烯的加入解决锂离子在斯派罗-OMeTAD 层中的移动问题。Nano Energy 2024; 129:110017.Qamar MZ, Khalid Z, Shahid R, et al. 通过自供电物联网应用的柔性过氧化物光伏技术推进室内能量收集。纳米能源 2024; 129:Tsvetkov N, Koo D, Kim D, et al:从材料到性能。Wang F, Duan DW, Sun YG, et al. Uncovering chemical structure-dependency of ionic liquids as additives for efficient and durable perovskite photovoltaics.张富强、郑德鑫、于大庆等:从优化到豁免。Zhou XY, Wu JW, Zeng J, et al. Target therapy on buried interface engineering enables stable inverted perovskite solar cells with 25% power conversion efficiency.Ling XF, Guo JJ, Li YP, et al. Chemical bath deposited antimony oxide thin films for efficient perovskite solar cells.Nano Letters 2024; 24(29):9065-9073.Wang WT, Holzhey P, Zhou N, et al.Nature 2024; 632(8025):Xiong SB, Tian FY, Wang F, et al.自然-通讯》,2024 年,第 15(1)期:5607.Zhang Y, Li CY, Zhao HY, et al.自然通讯 2024; 15(1):6887.Zhao CX, Zhou ZW, Almalki M, et al.自然通讯 2024; 15(1):Zhou HT, Cai K, Yu SQ, et al.自然通讯 2024; 15(1):6679.Tang HC, Shen ZC, Shen YZ, et al. Reinforcing self-assembly of hole transport molecules for stable inverted perovskite solar cells.Science 2024; 383(6688):1236-1240.Zhao XM, Zhang PK, Liu TJ, et al.433-438.Wang RS, Zhang PK, Liu TJ, et al:Wang RS, Li YF, Jia SS, et al. In situ vanadium modification induced a back interfacial field passivation effect toward efficient kesterite solar cells beyond 11% efficiency.Acs Applied Materials and Interfaces 2024; 16(35):Ding DL, Sun YL, Li WB, et al.Liu JL, Wu XY, Xue Y, et al. Se as hetero-nucleation seeds reinforcing intermetallic diffusion for improved electrodeposition-processed CZTS solar cells.Wang Y, Guo J, Siqin L, et al.太阳能材料和太阳能电池,2024;277:Seo G, Han S, Lee DG, et al.Chemical Engineering Journal 2024; 496: 154312.Araji MT, Waqas A, Ali R. Utilizing deep learning towards real-time snow cover detection and energy loss estimation for solar modules.应用能源 2024; 375: 124201.Fang M, Qian W, Qian T, et al. DGImNet:用于光伏污损估计的深度学习模型。Applied Energy 2024; 376: 124335.Hammam AH, Nayel MA, Mohamed MA.基于光伏系统的高速公路电动汽车充电站规模和分配的优化设计。Yao WX, Xu A, Kong XR, et al.Chang ZH, Jia KW, Han T, et al:有监督的检测视角。Energy Conversion and Management 2024; 316: 118845.Gong B, An A, Shi Y, et al. 应用能源 2025; 377: 124272.Zhao X, Li X, Liu T, et al:基于自我关注机制.能源 2024; 308: 132866.Gu QN, Li SF, Tian SH, et al:动态异质网络分析的证据.能源经济 2024; 137: 107775.Lin BQ, Liu YD.全球碳中和与中国的贡献:国际碳市场政策对中国光伏产品出口的影响.能源政策 2024;193:114299.Thonig R, Lilliestam J. Cross-technology legitimacy feedback:政策主导的聚光太阳能互补创新政治。Pan LW, Chen JJ, Zhao YL, et al. Towards optimal customized electricity pricing via iterative two-layer optimization for consumers and prosumers.Wang ZG, Liu Y, Gao F, et al. Environmental impact assessment of the manufacturing and use of n-type and p-type photovoltaic modules in China.Szabo L, Moner-Girona M, Jaeger-Waldau A, et al.自然通讯》,2024 年,第 15(1)期:6681.Soler-Castillo Y, Sahni M, Leon-Castro E. 基于两种新方法的光伏资源动态性能预测。光伏技术进展:研究与应用 2024; 32(10):701-745.Lee C-C, Wang C-W, Liu F.绿色信贷对新能源公司业绩的促进作用以及如何促进?研发投资和金融发展的作用.Renewable Energy 2024; 235: 121301.Liu Z, Guo J, Wang X, et al. Prediction of long-term photovoltaic power generation in the context of climate change.Renewable Energy 2024; 235: 121263.Yang BT, Huang YH, Chen CC.疏水性深共晶溶剂作为废弃光伏组件回收利用的新型介质。Sanathi R, Banerjee S, Bhowmik S. A technical review of crystalline silicon photovoltaic module recycling.太阳能 2024; 281:Gallegos MV, Gil-Escrig L, Zanoni KPS, et al:可持续发展的视角。太阳能材料和太阳能电池 2024; 277:Lee J-K、Ko S-W、Hwang H-M,et al.太阳能材料和太阳能电池 2024; 277:Su P、He Y、Feng Y 等.报废晶体硅光伏组件回收利用的进展:太阳能材料与太阳能电池,2024 年;277: 113102.Su P, He Y, Feng Y, et al.太阳能材料与太阳能电池》,2024 年,第 277 期:113109.Wahman M, Surowiak A, Ebin B, et al. 使用热刀技术从晶体硅组件中回收光伏背板。太阳能材料与太阳能电池 2024; 276: 113067.
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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”.
期刊最新文献
Issue Information Photovoltaics Literature Survey (No. 194) Issue Information Investigation of Potential-Induced Degradation and Recovery in Perovskite Minimodules Role of Ag Addition on the Microscopic Material Properties of (Ag,Cu)(In,Ga)Se2 Absorbers and Their Effects on Losses in the Open-Circuit Voltage of Corresponding Devices
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