PHOTOVOLTAICS LITERATURE SURVEY (No. 185)

IF 8 2区 材料科学 Q1 ENERGY & FUELS Progress in Photovoltaics Pub Date : 2023-09-03 DOI:10.1002/pip.3735
Ziv Hameiri
{"title":"PHOTOVOLTAICS LITERATURE SURVEY (No. 185)","authors":"Ziv Hameiri","doi":"10.1002/pip.3735","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>Parikh N, Akin S, Kalam A, et al <b>Probing the low-frequency response of impedance spectroscopy of halide perovskite single crystals using machine learning.</b> <i>Acs Applied Materials and Interfaces</i> 2023; <b>15</b>(23): 27801–27,808.</p><p>Du HQ, Jiang Y, Rothmann MU, et al <b>Transmission electron microscopy studies of organic–inorganic hybrid perovskites: Advances, challenges, and prospects.</b> <i>Applied Physics Reviews</i> 2023; <b>10</b>(2): 021314.</p><p>El Ainaoui K, Zaimi M, Assaid EM. <b>Innovative approaches to extract double-diode model physical parameters of a PV module serving outdoors under real-world conditions.</b> <i>Energy Conversion and Management</i> 2023; <b>292</b>: 117365.</p><p>Korovin A, Vasilev A, Egorov F, et al <b>Anomaly detection in electroluminescence images of heterojunction solar cells.</b> <i>Solar Energy</i> 2023; <b>259</b>: 130–136.</p><p>Panigrahi J, Pandey A, Bhattacharya S, et al <b>Impedance spectroscopy of amorphous/crystalline silicon heterojunction solar cells under dark and illumination.</b> <i>Solar Energy</i> 2023; <b>259</b>: 165–173.</p><p>Dwivedi P, Weber JW, Lee Chin R, et al <b>Deep learning method for enhancing luminescence image resolution.</b> <i>Solar Energy Materials and Solar Cells</i> 2023; <b>257</b>: 112357.</p><p>Vallerotto G, Martín F, Macías J, et al <b>Collimated solar simulator for curved PV modules characterization.</b> <i>Solar Energy Materials and Solar Cells</i> 2023; <b>258</b>: 112418.</p><p>Zhang HH, Zhang LP, Liu WZ, et al <b>Influence of intrinsic amorphous silicon passivation layer on the dark-state stability of SHJ cells.</b> <i>Applied Physics Letters</i> 2023; <b>122</b>(18): 182101.</p><p>Hammann B, Assmann N, Weiser PM, et al <b>The impact of different hydrogen configurations on light- and elevated-temperature- induced degradation.</b> <i>IEEE Journal of Photovoltaics</i> 2023; <b>13</b>(2): 224–235.</p><p>Rocha D, Alves J, Lopes V, et al <b>Multidefect detection tool for large-scale PV plants: Segmentation and classification.</b> <i>IEEE Journal of Photovoltaics</i> 2023; <b>13</b>(2): 291–295.</p><p>Hao B, Song YM, Jiang CH, et al <b>Comparing single-, double- and triple-layer anti-reflection coatings for ultra-low reflectance in silicon heterojunction solar cells.</b> <i>Japanese Journal of Applied Physics</i> 2023; <b>62</b>(6): 061002.</p><p>Geng Q, Wang Z, Liu Z, et al <b>Construction of V</b><sub><b>2</b></sub><b>O</b><sub><b>x</b></sub><b>/Si heterojunction and carrier-assisted collection for high-efficiency silicon solar cells.</b> <i>Materials Today Energy</i> 2023; <b>34</b>: 101317.</p><p>Liu WZ, Liu YJ, Yang ZQ, et al <b>Flexible solar cells based on foldable silicon wafers with blunted edges.</b> <i>Nature</i> 2023; <b>617</b>(7962): 717.</p><p>Arriaga Arruti O, Virtuani A, Ballif C. <b>Long-term performance and reliability of silicon heterojunction solar modules.</b> <i>Progress in Photovoltaics: Research and Applications</i> 2023; <b>31</b>(7): 664–677.</p><p>Lohmüller E, Baliozian P, Gutmann L, et al <b>TOPCon shingle solar cells: Thermal laser separation and passivated edge technology.</b> <i>Progress in Photovoltaics: Research and Applications</i> 2023; <b>31</b>(7): 729–737.</p><p>Lin N, Yang Z, Du H, et al <b>Excellent surface passivation of p-type TOPCon enabled by ozone-gas oxidation with a single-sided saturation current density of ∼ 4.5 fA/cm</b><sup><b>2</b></sup>. <i>Solar Energy</i> 2023; <b>259</b>: 348–355.</p><p>Abdul Fattah TO, Markevich VP, Gomes D, et al <b>Interactions of hydrogen atoms with boron and gallium in silicon crystals co-doped with phosphorus and acceptors.</b> <i>Solar Energy Materials and Solar Cells</i> 2023; <b>259</b>: 112447.</p><p>Chen H, Zhang J, Hu D, et al <b>Improving quality of cast monocrystalline Si ingot with seed crystal strips and graphite soft felt.</b> <i>Solar Energy Materials and Solar Cells</i> 2023; <b>258</b>: 112416.</p><p>Chen N, Tune D, Buchholz F, et al <b>Stable passivation of cut edges in encapsulated n-type silicon solar cells using Nafion polymer.</b> <i>Solar Energy Materials and Solar Cells</i> 2023; <b>258</b>: 112401.</p><p>Du H, Wang T, Liu W, et al <b>24.18% efficiency TOPCon solar cells enabled by super hydrophilic carbon-doped polysilicon films combined with plated metal fingers.</b> <i>Solar Energy Materials and Solar Cells</i> 2023; <b>257</b>: 112393.</p><p>Feng B, Liu Y, Chen W, et al <b>Differently shaped Ag crystallites and four current transport paths at sintered Ag/Si interface of crystalline silicon solar cells.</b> <i>Solar Energy Materials and Solar Cells</i> 2023; <b>257</b>: 112381.</p><p>Hammann B, Aßmann N, Schön J, et al <b>Understanding the impact of the cooling ramp of the fast-firing process on light- and elevated-temperature-induced degradation.</b> <i>Solar Energy Materials and Solar Cells</i> 2023; <b>259</b>: 112462.</p><p>Linke J, Hoß J, Buchholz F, et al <b>Influence of the annealing temperature of (n) poly-Si/SiO</b><sub><b>x</b></sub> <b>passivating contacts on their firing stability.</b> <i>Solar Energy Materials and Solar Cells</i> 2023; <b>258</b>: 112415.</p><p>Ma S, Liao B, Qiao FY, et al <b>24.7% industrial tunnel oxide passivated contact solar cells prepared through tube PECVD integrating with plasma-assisted oxygen oxidation and in-situ doped polysilicon.</b> <i>Solar Energy Materials and Solar Cells</i> 2023; <b>257</b>: 112396.</p><p>Wang Q, Peng H, Gu S, et al <b>High-efficiency n-TOPCon bifacial solar cells with selective poly-Si based passivating contacts.</b> <i>Solar Energy Materials and Solar Cells</i> 2023; <b>259</b>: 112458.</p><p>Wen L, Zhao L, Wang G, et al <b>Beyond 25% efficient crystalline silicon heterojunction solar cells with hydrogenated amorphous silicon oxide stacked passivation layers for rear emitter.</b> <i>Solar Energy Materials and Solar Cells</i> 2023; <b>258</b>: 112429.</p><p>Wratten A, Pain SL, Yadav A, et al <b>Exploring hafnium oxide's potential for passivating contacts for silicon solar cells.</b> <i>Solar Energy Materials and Solar Cells</i> 2023; <b>259</b>: 112457.</p><p>Xing H, Liu Z, Yang Z, et al <b>Plasma treatment for chemical SiO</b><sub><b>x</b></sub> <b>enables excellent passivation of p-type polysilicon passivating contact featuring the lowest J<sub>0</sub> of ∼6 fA/cm</b><sup><b>2</b></sup>. <i>Solar Energy Materials and Solar Cells</i> 2023; <b>257</b>: 112354.</p><p>Zhou J, Zhang J, Lv B. <b>Firing behavior of lead-containing and lead-free metallization silver paste for monocrystalline silicon solar cells.</b> <i>Solar Energy Materials and Solar Cells</i> 2023; <b>259</b>: 112439.</p><p>Zhou Y, Jia C, Lu K, et al <b>Energy-efficient colorful silicon photovoltaic modules driven by transparent-colored radiative cooling.</b> <i>Solar Energy Materials and Solar Cells</i> 2023; <b>259</b>: 112459.</p><p>Babics M, Bristow H, Pininti AR, et al <b>Temperature coefficients of perovskite/silicon tandem solar cells.</b> <i>Acs Energy Letters</i> 2023; <b>8</b>(7): 3013–3,015.</p><p>Chiang YH, Frohna K, Salway H, et al <b>Vacuum-deposited wide-bandgap perovskite for all-perovskite tandem solar cells.</b> <i>Acs Energy Letters</i> 2023; <b>8</b>(6): 2728–2,737.</p><p>Chittiboina GV, Singareddy A, Agarwal A, et al <b>Intrinsic degradation-dependent energy yield estimates for perovskite/silicon tandem solar cells under field conditions.</b> <i>Acs Energy Letters</i> 2023; <b>8</b>(7): 2927–2,934.</p><p>Xu LJ, Xu FZ, Liu J, et al <b>Bandgap optimization for bifacial tandem solar cells.</b> <i>Acs Energy Letters</i> 2023; <b>8</b>(7): 3114–3,121.</p><p>Wang XL, Ying ZQ, Zheng JM, et al <b>Long-chain anionic surfactants enabling stable perovskite/silicon tandems with greatly suppressed stress corrosion.</b> <i>Nature Communications</i> 2023; <b>14</b>(1): 2166.</p><p>Wang YR, Lin RX, Wang XY, et al <b>Oxidation-resistant all-perovskite tandem solar cells in substrate configuration.</b> <i>Nature Communications</i> 2023; <b>14</b>(1): 1819.</p><p>Gayathri RD, Lakshman C, Kim H, et al <b>Multifunctional narrow band gap terpolymer-enabled high-performance dopant-free perovskite and additive-free organic solar cells with long-term stability.</b> <i>Acs Applied Materials and Interfaces</i> 2023; <b>15</b>(26): 31514–31,524.</p><p>Guan H, Liao QG, Huang TH, et al <b>Solid additive enables organic solar cells with efficiency up to 18.6%.</b> <i>Acs Applied Materials and Interfaces</i> 2023; <b>15</b>(21): 25774–25,782.</p><p>Kaienburg P, Bristow H, Jungbluth A, et al <b>Vacuum-deposited donors for low-voltage-loss nonfullerene organic solar cells.</b> <i>Acs Applied Materials and Interfaces</i> 2023; <b>15</b>(26): 31684–31,691.</p><p>Zhang L, Yang F, Deng W, et al <b>Organic–inorganic hybrid cathode interlayer for efficient flexible inverted organic solar modules.</b> <i>Applied Physics Letters</i> 2023; 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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].

Parikh N, Akin S, Kalam A, et al Probing the low-frequency response of impedance spectroscopy of halide perovskite single crystals using machine learning. Acs Applied Materials and Interfaces 2023; 15(23): 27801–27,808.

Du HQ, Jiang Y, Rothmann MU, et al Transmission electron microscopy studies of organic–inorganic hybrid perovskites: Advances, challenges, and prospects. Applied Physics Reviews 2023; 10(2): 021314.

El Ainaoui K, Zaimi M, Assaid EM. Innovative approaches to extract double-diode model physical parameters of a PV module serving outdoors under real-world conditions. Energy Conversion and Management 2023; 292: 117365.

Korovin A, Vasilev A, Egorov F, et al Anomaly detection in electroluminescence images of heterojunction solar cells. Solar Energy 2023; 259: 130–136.

Panigrahi J, Pandey A, Bhattacharya S, et al Impedance spectroscopy of amorphous/crystalline silicon heterojunction solar cells under dark and illumination. Solar Energy 2023; 259: 165–173.

Dwivedi P, Weber JW, Lee Chin R, et al Deep learning method for enhancing luminescence image resolution. Solar Energy Materials and Solar Cells 2023; 257: 112357.

Vallerotto G, Martín F, Macías J, et al Collimated solar simulator for curved PV modules characterization. Solar Energy Materials and Solar Cells 2023; 258: 112418.

Zhang HH, Zhang LP, Liu WZ, et al Influence of intrinsic amorphous silicon passivation layer on the dark-state stability of SHJ cells. Applied Physics Letters 2023; 122(18): 182101.

Hammann B, Assmann N, Weiser PM, et al The impact of different hydrogen configurations on light- and elevated-temperature- induced degradation. IEEE Journal of Photovoltaics 2023; 13(2): 224–235.

Rocha D, Alves J, Lopes V, et al Multidefect detection tool for large-scale PV plants: Segmentation and classification. IEEE Journal of Photovoltaics 2023; 13(2): 291–295.

Hao B, Song YM, Jiang CH, et al Comparing single-, double- and triple-layer anti-reflection coatings for ultra-low reflectance in silicon heterojunction solar cells. Japanese Journal of Applied Physics 2023; 62(6): 061002.

Geng Q, Wang Z, Liu Z, et al Construction of V2Ox/Si heterojunction and carrier-assisted collection for high-efficiency silicon solar cells. Materials Today Energy 2023; 34: 101317.

Liu WZ, Liu YJ, Yang ZQ, et al Flexible solar cells based on foldable silicon wafers with blunted edges. Nature 2023; 617(7962): 717.

Arriaga Arruti O, Virtuani A, Ballif C. Long-term performance and reliability of silicon heterojunction solar modules. Progress in Photovoltaics: Research and Applications 2023; 31(7): 664–677.

Lohmüller E, Baliozian P, Gutmann L, et al TOPCon shingle solar cells: Thermal laser separation and passivated edge technology. Progress in Photovoltaics: Research and Applications 2023; 31(7): 729–737.

Lin N, Yang Z, Du H, et al Excellent surface passivation of p-type TOPCon enabled by ozone-gas oxidation with a single-sided saturation current density of ∼ 4.5 fA/cm2. Solar Energy 2023; 259: 348–355.

Abdul Fattah TO, Markevich VP, Gomes D, et al Interactions of hydrogen atoms with boron and gallium in silicon crystals co-doped with phosphorus and acceptors. Solar Energy Materials and Solar Cells 2023; 259: 112447.

Chen H, Zhang J, Hu D, et al Improving quality of cast monocrystalline Si ingot with seed crystal strips and graphite soft felt. Solar Energy Materials and Solar Cells 2023; 258: 112416.

Chen N, Tune D, Buchholz F, et al Stable passivation of cut edges in encapsulated n-type silicon solar cells using Nafion polymer. Solar Energy Materials and Solar Cells 2023; 258: 112401.

Du H, Wang T, Liu W, et al 24.18% efficiency TOPCon solar cells enabled by super hydrophilic carbon-doped polysilicon films combined with plated metal fingers. Solar Energy Materials and Solar Cells 2023; 257: 112393.

Feng B, Liu Y, Chen W, et al Differently shaped Ag crystallites and four current transport paths at sintered Ag/Si interface of crystalline silicon solar cells. Solar Energy Materials and Solar Cells 2023; 257: 112381.

Hammann B, Aßmann N, Schön J, et al Understanding the impact of the cooling ramp of the fast-firing process on light- and elevated-temperature-induced degradation. Solar Energy Materials and Solar Cells 2023; 259: 112462.

Linke J, Hoß J, Buchholz F, et al Influence of the annealing temperature of (n) poly-Si/SiOx passivating contacts on their firing stability. Solar Energy Materials and Solar Cells 2023; 258: 112415.

Ma S, Liao B, Qiao FY, et al 24.7% industrial tunnel oxide passivated contact solar cells prepared through tube PECVD integrating with plasma-assisted oxygen oxidation and in-situ doped polysilicon. Solar Energy Materials and Solar Cells 2023; 257: 112396.

Wang Q, Peng H, Gu S, et al High-efficiency n-TOPCon bifacial solar cells with selective poly-Si based passivating contacts. Solar Energy Materials and Solar Cells 2023; 259: 112458.

Wen L, Zhao L, Wang G, et al Beyond 25% efficient crystalline silicon heterojunction solar cells with hydrogenated amorphous silicon oxide stacked passivation layers for rear emitter. Solar Energy Materials and Solar Cells 2023; 258: 112429.

Wratten A, Pain SL, Yadav A, et al Exploring hafnium oxide's potential for passivating contacts for silicon solar cells. Solar Energy Materials and Solar Cells 2023; 259: 112457.

Xing H, Liu Z, Yang Z, et al Plasma treatment for chemical SiOx enables excellent passivation of p-type polysilicon passivating contact featuring the lowest J0 of ∼6 fA/cm2. Solar Energy Materials and Solar Cells 2023; 257: 112354.

Zhou J, Zhang J, Lv B. Firing behavior of lead-containing and lead-free metallization silver paste for monocrystalline silicon solar cells. Solar Energy Materials and Solar Cells 2023; 259: 112439.

Zhou Y, Jia C, Lu K, et al Energy-efficient colorful silicon photovoltaic modules driven by transparent-colored radiative cooling. Solar Energy Materials and Solar Cells 2023; 259: 112459.

Babics M, Bristow H, Pininti AR, et al Temperature coefficients of perovskite/silicon tandem solar cells. Acs Energy Letters 2023; 8(7): 3013–3,015.

Chiang YH, Frohna K, Salway H, et al Vacuum-deposited wide-bandgap perovskite for all-perovskite tandem solar cells. Acs Energy Letters 2023; 8(6): 2728–2,737.

Chittiboina GV, Singareddy A, Agarwal A, et al Intrinsic degradation-dependent energy yield estimates for perovskite/silicon tandem solar cells under field conditions. Acs Energy Letters 2023; 8(7): 2927–2,934.

Xu LJ, Xu FZ, Liu J, et al Bandgap optimization for bifacial tandem solar cells. Acs Energy Letters 2023; 8(7): 3114–3,121.

Wang XL, Ying ZQ, Zheng JM, et al Long-chain anionic surfactants enabling stable perovskite/silicon tandems with greatly suppressed stress corrosion. Nature Communications 2023; 14(1): 2166.

Wang YR, Lin RX, Wang XY, et al Oxidation-resistant all-perovskite tandem solar cells in substrate configuration. Nature Communications 2023; 14(1): 1819.

Gayathri RD, Lakshman C, Kim H, et al Multifunctional narrow band gap terpolymer-enabled high-performance dopant-free perovskite and additive-free organic solar cells with long-term stability. Acs Applied Materials and Interfaces 2023; 15(26): 31514–31,524.

Guan H, Liao QG, Huang TH, et al Solid additive enables organic solar cells with efficiency up to 18.6%. Acs Applied Materials and Interfaces 2023; 15(21): 25774–25,782.

Kaienburg P, Bristow H, Jungbluth A, et al Vacuum-deposited donors for low-voltage-loss nonfullerene organic solar cells. Acs Applied Materials and Interfaces 2023; 15(26): 31684–31,691.

Zhang L, Yang F, Deng W, et al Organic–inorganic hybrid cathode interlayer for efficient flexible inverted organic solar modules. Applied Physics Letters 2023; 122(26): 263903.

Zhou H, Zhang L, Ma XL, et al Approaching 18% efficiency of ternary layer-by-layer polymer solar cells with alloyed acceptors. Chemical Engineering Journal 2023; 462: 142327.

Chen ZH, Yao HF, Wang JW, et al Restrained energetic disorder for high-efficiency organic solar cells via a solid additive. Energy and Environmental Science 2023; 16(6): 2637–2,645.

Chen ZY, Zhu JT, Yang DB, et al Isomerization strategy on a non-fullerene guest acceptor for stable organic solar cells with over 19% efficiency. Energy and Environmental Science 2023; 16(7): 3119–3,127.

Ma RJ, Jiang XY, Fu JH, et al Revealing the underlying solvent effect on film morphology in high-efficiency organic solar cells through combined ex situ and in situ observations. Energy and Environmental Science 2023; 16(5): 2316–2,326.

Huang YZ, Si XD, Wang RH, et al A polymer acceptor with grafted small molecule acceptor units for high-efficiency organic solar cells. Journal of Materials Chemistry A 2023; 11(27): 14768–14,775.

Gu CT, Zhao Y, Liu B, et al Regioregular polymerized small-molecule acceptors for high-performance all-polymer solar cells. Journal of Materials Chemistry C 2023; 11(27): 9082–9,092.

Li ZX, Jiang CZ, Chen X, et al Side-chain modification of non-fullerene acceptors for organic solar cells with efficiency over 18%. Journal of Materials Chemistry C 2023; 11(21): 6920–6,927.

Wan QP, Seo S, Lee SW, et al High-performance intrinsically stretchable polymer solar cell with record efficiency and stretchability enabled by thymine-functionalized terpolymer. Journal of the American Chemical Society 2023; 145(22): 11914–11,920.

Tsao CS, Chuang CM, Cha HC, et al Lab-to-Fab development and long-term greenhouse test of stable flexible semitransparent organic photovoltaic module. Materials Today Energy 2023; 36: 101340.

An K, Zhong WK, Peng F, et al Mastering morphology of non-fullerene acceptors towards long-term stable organic solar cells. Nature Communications 2023; 14(1): 2688.

Lai X, Chen SY, Gu XY, et al Phenanthroline-carbolong interface suppress chemical interactions with active layer enabling long-time stable organic solar cells. Nature Communications 2023; 14(1): 3571.

Liu B, Sun HL, Lee JW, et al Efficient and stable organic solar cells enabled by multicomponent photoactive layer based on one-pot polymerization. Nature Communications 2023; 14(1): 967.

Galdino JJB, Vilela OdC, Fraidenraich N, et al Evaluation of front and backside performances of a large surface organic photovoltaic module under bifacial illumination. Solar Energy Materials and Solar Cells 2023; 257: 112359.

Bae JH, Jeon HJ, Cho SH, et al Efficiency improvement of dye-sensitized solar cells using Cu,Co/TiO2 photoelectrodes doped by applying ultrasonic treatment. Applied Surface Science 2023; 621: 156823.

Speranza R, Reina M, Zaccagnini P, et al Laser-induced graphene as a sustainable counter electrode for DSSC enabling flexible self-powered integrated harvesting and storage device for indoor application. Electrochimica Acta 2023; 460: 142614.

Chumwangwapee N, Suksri A, Wongwuttanasatian T. Investigation of bi-colour natural dyes potential for dye sensitized solar cell. Energy Reports 2023; 9: 415–421.

Kaur N, Syed FM, Fina J, et al Ag reflectors: An effective approach to improve light harvesting in dye sensitized solar cells. IEEE Journal of Photovoltaics 2023; 13(2): 250–253.

Jagadeesh A, Veerappan G, Devi PS, et al Synergetic effect of TiO2/ZnO bilayer photoanodes realizing exceptionally high VOC for dye-sensitized solar cells under outdoor and indoor illumination. Journal of Materials Chemistry A 2023; 11(27): 14748–14,759.

Bifari EN, Almeida P, El-Shishtawy RM. Advancing panchromatic effect for efficient sensitization of cyanine and hemicyanine-based dye-sensitized solar cells. Materials Today Energy 2023; 36: 101337.

He Y, Yue G, Huo J, et al A dye-sensitized solar cells with an efficiency of 10.01% based on the MoP/MoNiP2@Ti3C2 composite counter electrode. Materials Today Sustainability 2023; 22: 100329.

Dong JJ, Yan SH, Chen HY, et al Approaching full-scale passivation in perovskite solar cells via valent-variable carbazole cations. Acs Energy Letters 2023; 8(6): 2772–2,780.

Kedia M, Rai M, Phirke H, et al Light makes right: Laser polishing for surface modification of perovskite solar cells. Acs Energy Letters 2023; 8(6): 2603–2,610.

Li MY, Park SY, Wang JX, et al Nickel-doped graphite and fusible alloy bilayer back electrode for vacuum-free perovskite solar cells. Acs Energy Letters 2023; 8(7): 2940–2,945.

Martani S, Zhou Y, Poli I, et al Defect engineering to achieve photostable wide bandgap metal halide perovskites. Acs Energy Letters 2023; 8(6): 2801–2,808.

Zhang X, Qiu WM, Apergi S, et al Minimizing the interface-driven losses in inverted perovskite solar cells and modules. Acs Energy Letters 2023; 8(6): 2532–2,542.

An MW, Li BL, Chen BW, et al Star-like, dopant-free, corannulene-cored hole transporting materials for efficient inverted perovskite solar cells. Chemical Engineering Journal 2023; 470: 144056.

Lv Y, Wang K, Lan A, et al Low-photovoltage-loss pringting perovskite solar cells in ambient air through ink synergistic engineering. Chemical Engineering Journal 2023; 469: 143909.

Wang R, Altujjar A, Zibouche N, et al Improving the efficiency and stability of perovskite solar cells using pi-conjugated aromatic additives with differing hydrophobicities. Energy and Environmental Science 2023; 16(6): 2646–2,657.

Jeong MJ, Moon CS, Lee S, et al Boosting radiation of stacked halide layer for perovskite solar cells with efficiency over 25%. Joule 2023; 7(1): 112–127.

Afroz MA, Singh A, Gupta RK, et al Design potential and future prospects of lead-free halide perovskites in photovoltaic devices. Journal of Materials Chemistry A 2023; 11(25): 13133–13,173.

Kim JH, Kang DH, Lee DN, et al Effect of functional groups in passivating materials on stability and performance of perovskite solar cells. Journal of Materials Chemistry A 2023; 11(27): 15014–15,021.

Duijnstee EA, Gallant BM, Holzhey P, et al Understanding the degradation of methylenediammonium and its role in phase-stabilizing formamidinium lead triiodide. Journal of the American Chemical Society 2023; 145(18): 10275–10,284.

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Pu XY, Zhao JS, Li YJ, et al Stable NiOx-based inverted perovskite solar cells achieved by passivation of multifunctional star polymer. Nano Energy 2023; 112: 108506.

Yang Y, Liu L, Li JX, et al Ambient-aging process enables enhanced efficiency for wide-bandgap perovskite solar cells. Nano Energy 2023; 109: 108288.

Jiang NR, Zhang HW, Liu YF, et al Transfer-imprinting-assisted growth of 2D/3D perovskite heterojunction for efficient and stable flexible inverted perovskite solar cells. Nano Letters 2023; 23(13): 6116–6,123.

Zhang H, Lee JW, Nasti G, et al Lead immobilization for environmentally sustainable perovskite solar cells. Nature 2023; 617(7962): 687–695.

Wang T, Yang JB, Cao Q, et al Room temperature nondestructive encapsulation via self-crosslinked fluorosilicone polymer enables damp heat-stable sustainable perovskite solar cells. Nature Communications 2023; 14(1): 1342.

Li CW, Wang XM, Bi EB, et al Rational design of Lewis base molecules for stable and efficient inverted perovskite solar cells. Science 2023; 379(6633): 690–694.

Peng W, Mao KT, Cai FC, et al Reducing nonradiative recombination in perovskite solar cells with a porous insulator contact. Science 2023; 379(6633): 683–690.

Zhang S, Ye FY, Wang XY, et al Minimizing buried interfacial defects for efficient inverted perovskite solar cells. Science 2023; 380(6643): 404–409.

Wei H, Li YM, Cui CC, et al Defect suppression for high-efficiency kesterite CZTSSe solar cells: Advances and prospects. Chemical Engineering Journal 2023; 462: 142121.

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Xiao Q, Kou DX, Zhou WH, et al Defect engineering of solution-processed ZnO:Li window layers towards high-efficiency and low-cost kesterite photovoltaics. Journal of Materials Chemistry A 2023; 11(21): 11161–11,169.

Zhao XY, Qi YF, Zhou ZJ, et al Regulating charge carrier recombination in Cu2ZnSn(S,Se)4 solar cells via cesium treatment: bulk and interface effects. Journal of Materials Chemistry A 2023; 11(21): 11454–11,462.

Fukuda R, Nishimura T, Yamada A. Experimental and theoretical EBIC analysis for grain boundary and CdS/Cu(In, Ga)Se2 heterointerface in Cu(In, Ga)Se2 solar cells. Progress in Photovoltaics: Research and Applications 2023; 31(7): 678–689.

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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
Cover Image Issue Information PHOTOVOLTAICS LITERATURE SURVEY (No. 195) Solar Cell Efficiency Tables (Version 65) Issue Information
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