Portal de Periódicos da CAPES

Photovoltaics literature survey (No. 162)

2020; Wiley; Volume: 28; Issue: 12 Linguagem: Inglês

10.1002/pip.3377

1099-159X

Ziv Hameiri,

Perovskite Materials and Applications

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 ziv.hameiri@unsw.edu.au. Reb LK, Bohmer M, Predeschly B, et al. Perovskite and organic solar cells on a rocket flight. Joule 2020; 4(9): 1880–1892. Ji CG, Liu D, Zhang C, et al. Ultrathin-metal-film-based transparent electrodes with relative transmittance surpassing 100%. Nature Communications 2020; 11(1): 3367. Yin J, Molini A, Porporato A. Impacts of solar intermittency on future photovoltaic reliability. Nature Communications 2020; 11(1): 4781. Guthrey H, Moseley J. A review and perspective on cathodoluminescence analysis of halide perovskites. Advanced Energy Materials 2020; 10(26): 1903840. Howard JM, Lahoti R, Leite MS. Imaging metal halide perovskites material and properties at the nanoscale. Advanced Energy Materials 2020; 10(26): 1903161. Kirchartz T, Maacuterquez JA, Stolterfoht M, et al. Photoluminescence-based characterization of halide perovskites for photovoltaics. Advanced Energy Materials 2020; 10(26): 1904134. Kodur M, Kumar RE, Yanqi L, et al. X-ray microscopy of halide perovskites: Techniques, applications, and prospects. Advanced Energy Materials 2020; 10(26): 1903170. Miyano K, Yanagida M, Shirai Y. Impedance spectroscopy revisited. Advanced Energy Materials 2020; 10(26): 1903097. Mundt LE, Schelhas LT. Structural evolution during perovskite crystal formation and degradation: In situ and operando x-ray diffraction studies. Advanced Energy Materials 2020; 10(26): 1903074. Hamadani BH. Understanding photovoltaic energy losses under indoor lighting conditions. Applied Physics Letters 2020; 117(4): 043904. Asadpour R, Sulas-Kern DB, Johnston S, et al. Dark lock-in thermography identifies solder bond failure as the root cause of series resistance increase in fielded solar modules. IEEE Journal of Photovoltaics 2020; 10(5): 1409–1416. Owen-Bellini M, Sulas-Kern DB, Perrin G, et al. Methods for in situ electroluminescence imaging of photovoltaic modules under varying environmental conditions. IEEE Journal of Photovoltaics 2020; 10(5): 1254–1261. Lee H. Investigation of charge-transport properties in polymer/fullerene blends using transient electroluminescence technique. Japanese Journal of Applied Physics 2020; 59(8): 081004. Chen SL, Gao P. Challenges, myths, and opportunities of electron microscopy on halide perovskites. Journal of Applied Physics 2020; 128(1): 010901. Nunomura S, Sakata I, Sakakita H, et al. Real-time monitoring of surface passivation of crystalline silicon during growth of amorphous and epitaxial silicon layer. Journal of Applied Physics 2020; 128(3): 033302. Rietwyk KJ, Tan BE, Surmiak A, et al. Light intensity modulated photoluminescence for rapid series resistance mapping of perovskite solar cells. Nano Energy 2020; 73: 104755. Buratti Y, Gia QTL, Dick J, et al. Extracting bulk defect parameters in silicon wafers using machine learning models. npj Computational Materials 2020; 6(1): 142. Li JY, Pan TY, Wang JL, et al. Bilayer MoOx/CrOx passivating contact targeting highly stable silicon heterojunction solar cells. Acs Applied Materials and Interfaces 2020; 12(32): 36778–36786. Bondareva JV, Aslyamov TF, Kvashnin AG, et al. Environmentally friendly method of silicon recycling: Synthesis of silica nanoparticles in an aqueous solution. Acs Sustainable Chemistry and Engineering 2020; 8(37): 14006–14012. Chen JH, Wan L, Li H, et al. A polymer/carbon-nanotube ink as a boron-dopant/inorganic-passivation free carrier selective contact for silicon solar cells with over 21% efficiency. Advanced Functional Materials 2020; 30(38): 2004476. Zhou Y, Tao K, Liu AM, et al. Study of boron diffusion for p+ emitter of large area n-type TOPCon silicon solar cells. Applied Physics a-Materials Science and Processing 2020; 126(9): 671. Hasan A, Dincer I. A new performance assessment methodology of bifacial photovoltaic solar panels for offshore applications. Energy Conversion and Management 2020; 220: 112972. Adrian A, Rudolph D, Willenbacher N, et al. Finger metallization using pattern transfer printing technology for c-Si solar cell. IEEE Journal of Photovoltaics 2020; 10(5): 1290–1298. Chen WH, Stuckelberger J, Wang WJ, et al. Influence of PECVD deposition power and pressure on phosphorus-doped polysilicon passivating contacts. IEEE Journal of Photovoltaics 2020; 10(5): 1239–1245. Conrad B, Antognini L, Amalathas AP, et al. Illumination-dependent requirements for heterojunctions and carrier-selective contacts on silicon. IEEE Journal of Photovoltaics 2020; 10(5): 1214–1225. Li MJ, Iqbal N, Yang ZH, et al. A comprehensive evaluation of contact recombination and contact resistivity losses in industrial silicon solar cells. IEEE Journal of Photovoltaics 2020; 10(5): 1277–1,282. Liang TS, Pravettoni M, Singh JP, et al. A metrological study of accurate indoor characterisation of commercial bifacial photovoltaic module with single light source. IEEE Journal of Photovoltaics 2020; 10(5): 1448–1454. Merhi H, Fell A, Grubel B, et al. Inhomogeneity of plated contacts for c-Si solar cells and their impact on solar cell efficiency. IEEE Journal of Photovoltaics 2020; 10(5): 1455–1462. Okasha A, Richter A, Saint-Cast P, et al. Ultrathin plasma oxide for passivation of phosphorus-diffused silicon solar cell emitters. IEEE Journal of Photovoltaics 2020; 10(5): 1226–1231. Rajput AS, Zhang Y, Rodriguez-Gallegos CD, et al. Comparative study of the electrical parameters of individual solar cells in a c-Si module extracted using indoor and outdoor electroluminescence imaging. IEEE Journal of Photovoltaics 2020; 10(5): 1396–1,402. Wagner-Mohnsen H, Altermatt PP. A combined numerical modeling and machine learning approach for optimization of mass-produced industrial solar cells. IEEE Journal of Photovoltaics 2020; 10(5): 1441–1447. Weber J, Brand A. A scanning spreading resistance microscopy study on a laser-doped selective phosphorous emitter. IEEE Journal of Photovoltaics 2020; 10(5): 1313–1318. Western NJ, Bremner SP. Hydrogenation and gettering compatible p-type contacts for multicrystalline silicon cells, free of light, and elevated temperature induced degradation. IEEE Journal of Photovoltaics 2020; 10(5): 1232–1238. Wilkes GC, Upadhyaya AD, Rohatgi A, et al. Laser crystallization and dopant activation of a-Si:H carrier-selective layer in TOPCon Si solar cells. IEEE Journal of Photovoltaics 2020; 10(5): 1283–1289. Wyss P, Stuckelberger J, Nogay G, et al. A mixed-phase SiOx hole selective junction compatible with high temperatures used in industrial solar cell manufacturing. IEEE Journal of Photovoltaics 2020; 10(5): 1262–1269. Li ZF, Zhang LP, Wu ZP, et al. Improved performance of silicon heterojunction solar cells via 3x three-step boron-doping. Journal of Applied Physics 2020; 128(4): 045309. Augusto A, Karas J, Balaji P, et al. Exploring the practical efficiency limit of silicon solar cells using thin solar-grade substrates. Journal of Materials Chemistry A 2020; 8(32): 16599–16608. Dao VA, Trinh TT, Kim S, et al. Carrier transport mechanisms of reactively direct current magnetron sputtered tungsten oxide/n-type crystalline silicon heterojunction. Journal of Power Sources 2020; 472(228460). Durusoy B, Ozden T, Akinoglu BG. Solar irradiation on the rear surface of bifacial solar modules: A modeling approach. Scientific Reports 2020; 10(1): 13300. Hollemann C, Haase F, Rienacker M, et al. Separating the two polarities of the POLO contacts of an 26.1%-efficient IBC solar cell. Scientific Reports 2020; 10(1): 658. Stefani BV, Soeriyadi A, Wright M, et al. Large-area boron-doped 1.6 omega cm p-type Czochralski silicon heterojunction solar cells with a stable open-circuit voltage of 736 mV and efficiency of 22.0%. Solar RRL 2020; 4(9): 2000134. Jeong S, Park B, Hong S, et al. Large-area nonfullerene organic solar cell modules fabricated by a temperature-independent printing method. Acs Applied Materials and Interfaces 2020; 12(37): 41877–41,885. Zhang K, Ying L, Yip HL, et al. Toward efficient tandem organic solar cells: From materials to device engineering. Acs Applied Materials and Interfaces 2020; 12(36): 39937–39947. Lin YB, Firdaus Y, Isikgor FH, et al. Self-assembled monolayer enables hole transport layer-free organic solar cells with 18% efficiency and improved operational stability. Acs Energy Letters 2020; 5(9): 2935–2944. Qiang P, He Y, Xiaopeng X, et al. Highly efficient all-polymer solar cells enabled by p-doping of the polymer donor. Acs Energy Letters 2020; 5(7): 135–144. Hoi Yi Ho C, Taesoo K, Yuan X, et al. High-performance tandem organic solar cells using HSolar as the interconnecting layer. Advanced Energy Materials 2020; 10(25): 2000823. Xiaoling M, Jian W, Jinhua G, et al. Achieving 17.4% efficiency of ternary organic photovoltaics with two well-compatible nonfullerene acceptors for minimizing energy loss. Advanced Energy Materials 2020; 10(31): 2001404. Qin JQ, Lan LK, Chen SS, et al. Recent progress in flexible and stretchable organic solar cells. Advanced Functional Materials 2020; 30(36): 2002529. Azeez A, Narayan KS. Enhanced device performance via interfacial engineering in non-fullerene acceptor based organic solar cells. Applied Physics Letters 2020; 117(4): 043302. Zhang LL, Hao YY, Gao K. Efficient quantum theory for studying cold charge-transfer state dissociations in donor-acceptor heterojunction organic solar cells. Applied Physics Letters 2020; 117(12): 123301. Kim SM, Saeed MA, Kim SH, et al. Enhanced hole selecting behavior of WO3 interlayers for efficient indoor organic photovoltaics with high fill-factor. Applied Surface Science 2020; 527: 146840. Lin BJ, Zhou XB, Zhao H, et al. Balancing the pre-aggregation and crystallization kinetics enables high efficiency slot-die coated organic solar cells with reduced non-radiative recombination losses. Energy and Environmental Science 2020; 13(8): 2467–2479. Wu JY, Lee J, Chin YC, et al. Exceptionally low charge trapping enables highly efficient organic bulk heterojunction solar cells. Energy and Environmental Science 2020; 13(8): 2422–2430. Yang CY, Zhang SQ, Ren JZ, et al. Molecular design of a non-fullerene acceptor enables a P3HT-based organic solar cell with 9.46% efficiency. Energy and Environmental Science 2020; 13(9): 2864–2869. Zhu C, Yuan J, Cai FF, et al. Tuning the electron-deficient core of a non-fullerene acceptor to achieve over 17% efficiency in a single-junction organic solar cell. Energy and Environmental Science 2020; 13(8): 2459–2466. Arunagiri L, Peng ZX, Zou XH, et al. Selective hole and electron transport in efficient quaternary blend organic solar cells. Joule 2020; 4(8): 1790–1805. Dong S, Jia T, Zhang K, et al. Single-component non-halogen solvent-processed high-performance organic solar cell module with efficiency over 14%. Joule 2020; 4(9): 2004–2016. Ma LK, Chen YZ, Chow PCY, et al. High-efficiency indoor organic photovoltaics with a band-aligned interlayer. Joule 2020; 4(7): 1486–1,500. Cai FF, Peng HJ, Chen HG, et al. An asymmetric small molecule acceptor for organic solar cells with a short circuit current density over 24 mA.cm−2. Journal of Materials Chemistry A 2020; 8(31): 15984–15991. He CL, Li YK, Liu YF, et al. Near infrared electron acceptors with a photoresponse beyond 1,000 nm for highly efficient organic solar cells. Journal of Materials Chemistry A 2020; 8(35): 18154–18161. Huang S, Duan L, Zhang DD. Synergistic optimization of interfacial energy-level alignment and defect passivation toward efficient annealing-free inverted polymer solar cells. Journal of Materials Chemistry A 2020; 8(36): 18792–18801. Cho Y, Kumari T, Jeong S, et al. Guest-oriented non-fullerene acceptors for ternary organic solar cells with over 16.0% and 22.7% efficiencies under one-sun and indoor light. Nano Energy 2020; 75: 104896. Ke X, Meng LX, Wan XJ, et al. A nonfullerene acceptor incorporating a dithienopyran fused backbone for organic solar cells with efficiency over 14%. Nano Energy 2020; 75: 104988. Zhang GC, Chen XK, Xiao JY, et al. Delocalization of exciton and electron wavefunction in non-fullerene acceptor molecules enables efficient organic solar cells. Nature Communications 2020; 11(1): 3943. Wu Y, Guo J, Sun R, et al. Machine learning for accelerating the discovery of high-performance donor/acceptor pairs in non-fullerene organic solar cells. npj Computational Materials 2020; 6(1): 120. Kashif M, Ngaini Z, Harry AV, et al. An experimental and DFT study on novel dyes incorporated with natural dyes on titanium dioxide (TiO2) towards solar cell application. Applied Physics a-Materials Science and Processing 2020; 126(9): 716. Xia J, Wang Q, Xu QQ, et al. High efficiency bifacial quasi-solid-state dye-sensitized solar cell based on CoSe2 nanorod counter electrode. Applied Surface Science 2020; 530: 147238. Mehmood U, Ahmad SHA, Al-Ahmed A, et al. Synthesis and characterization of cerium oxide impregnated titanium oxide photoanodes for efficient dye-sensitized solar cells. IEEE Journal of Photovoltaics 2020; 10(5): 1365–1370. Yu-Hsun N, Hui-Hsuan H, Geng-Ming H, et al. Study of novel dye-sensitized solar cells with modified photoelectrode by ZrO2 and rGO doped TiO2 composite nanofibers. IEEE Transactions on Electron Devices 2020; 67(9): 3660. Byeon J, Kim J, Kim JY, et al. Charge transport layer-dependent electronic band bending in perovskite solar cells and its correlation to light-induced device degradation. Acs Energy Letters 2020; 5(8): 2580–2589. Jagt RA, Huq TN, Hill SA, et al. Rapid vapor-phase deposition of high-mobility p-type buffer layers on perovskite photovoltaics for efficient semitransparent devices. Acs Energy Letters 2020; 5(8): 2456–2465. Kang YJ, Kwon SN, Cho SP, et al. Antisolvent additive engineering containing dual-function additive for triple-cation p-i-n perovskite solar cells with over 20% PCE. Acs Energy Letters 2020; 5(8): 2535–2545. Xiao K, Wen J, Han QL, et al. Solution-processed monolithic all-perovskite triple-junction solar cells with efficiency exceeding 20%. Acs Energy Letters 2020; 5(9): 2819–2826. Dedecker K, Grancini G. Dealing with lead in hybrid perovskite: A challenge to tackle for a bright future of this technology? Advanced Energy Materials 2020; 10(31): 2001471. Di Girolamo D, Nga P, Kosasih FU, et al. Ion migration-induced amorphization and phase segregation as a degradation mechanism in planar perovskite solar cells. Advanced Energy Materials 2020; 10(25): 2000310. Joscaront M, Kegelmann L, Korte L, et al. Monolithic perovskite tandem solar cells: A review of the present status and advanced characterization methods toward 30% efficiency. Advanced Energy Materials 2020; 10(26): 1904102. Jost M, Lipovsek B, Glazar B, et al. Perovskite solar cells go outdoors: Field testing and temperature effects on energy yield. Advanced Energy Materials 2020; 10(25): 2000454. Wang B, Zhang M, Cui X, et al. Unconventional route to oxygen-vacancy-enabled highly efficient electron extraction and transport in perovskite solar cells. Angewandte Chemie-International Edition 2020; 59(4): 1611–1618. Wang XT, Wang Y, Zhang TY, et al. Steric mixed-cation 2D perovskite as a methylammonium locker to stabilize MAPbI3. Angewandte Chemie-International Edition 2020; 59(4): 1469–1473. Lin BJ, Zhou XB, Zhao H, et al. Balancing the pre-aggregation and crystallization kinetics enables high efficiency slot-die coated organic solar cells with reduced non-radiative recombination losses. Energy and Environmental Science 2020; 13(8): 2467–2479. Nie RM, Sumukam RR, Reddy SH, et al. Lead-free perovskite solar cells enabled by hetero-valent substitutes. Energy and Environmental Science 2020; 13(8): 2363–2385. Boyd CC, Shallcross RC, Moot T, et al. Overcoming redox reactions at perovskite-nickel oxide interfaces to boost voltages in perovskite solar cells. Joule 2020; 4(8): 1759–1775. Chen YH, Tan SQ, Li NX, et al. Self-elimination of intrinsic defects improves the low-temperature performance of perovskite photovoltaics. Joule 2020; 4(9): 1961–1976. He JL, Fang WH, Long R, et al. Why oxygen increases carrier lifetimes but accelerates degradation of CH3NH3PbI3 under light irradiation: Time-domain Ab initio analysis. Journal of the American Chemical Society 2020; 142(34): 14664–14673. Kim TW, Park NG. Methodologies for structural investigations of organic lead halide perovskites. Materials Today 2020; 38: 67–83. Bu TL, Li J, Lin QD, et al. Structure engineering of hierarchical layered perovskite interface for efficient and stable wide bandgap photovoltaics. Nano Energy 2020; 75: 104917. Jiang XQ, Zhang JF, Ahmad S, et al. Dion-Jacobson 2D-3D perovskite solar cells with improved efficiency and stability. Nano Energy 2020; 75: 104892. Laska M, Krzeminska Z, Kluczyk-Korch K, et al. Metallization of solar cells, exciton channel of plasmon photovoltaic effect in perovskite cells. Nano Energy 2020; 75: 104751. Lim JW, Kwon H, Kim SH, et al. Unprecedentedly high indoor performance (efficiency >34%) of perovskite photovoltaics with controlled bromine doping. Nano Energy 2020; 75: 104984. Liu GZ, Zheng HY, Xu HF, et al. Interface passivation treatment by halogenated low-dimensional perovskites for high-performance and stable perovskite photovoltaics. Nano Energy 2020; 73: 104753. Yang JM, Bao QY, Shen L, et al. Potential applications for perovskite solar cells in space. Nano Energy 2020; 76: 105019. Li DL, Chao LF, Chen CS, et al. In situ interface engineering for highly efficient electron-transport-layer-free perovskite solar cells. Nano Letters 2020; 20(8): 5799–5806. Lei YS, Chen YM, Zhang RQ, et al. A fabrication process for flexible single-crystal perovskite devices. Nature 2020; 583(7818): 790. Alvar MS, Blom PWM, Wetzelaer G. Space-charge-limited electron and hole currents in hybrid organic–inorganic perovskites. Nature Communications 2020; 11(1): 4023. Hartono NTP, Thapa J, Tiihonen A, et al. How machine learning can help select capping layers to suppress perovskite degradation. Nature Communications 2020; 11(1): 4172. He TW, Li SS, Jiang YZ, et al. Reduced-dimensional perovskite photovoltaics with homogeneous energy landscape. Nature Communications 2020; 11(1): 1672. Kim H, Kim JS, Heo JM, et al. Proton-transfer-induced 3D/2D hybrid perovskites suppress ion migration and reduce luminance overshoot. Nature Communications 2020; 11(1): 3378. Liu X, Wang YB, Wu TH, et al. Efficient and stable tin perovskite solar cells enabled by amorphous-polycrystalline structure. Nature Communications 2020; 11(1): 2678. Meng XC, Cai ZR, Zhang YY, et al. Bio-inspired vertebral design for scalable and flexible perovskite solar cells. Nature Communications 2020; 11(1): 3016. Quan L, Ma DX, Zhao YB, et al. Edge stabilization in reduced-dimensional perovskites. Nature Communications 2020; 11(1): 170. Wang J, Zhang J, Zhou YZ, et al. Highly efficient all-inorganic perovskite solar cells with suppressed non-radiative recombination by a Lewis base. Nature Communications 2020; 11(1): 177. Jeong M, Choi IW, Go EM, et al. Stable perovskite solar cells with efficiency exceeding 24.8% and 0.3-V voltage loss. Science 2020; 369(6511): 1615. Baines T, Bowen L, Mendis BG, et al. Microscopic analysis of interdiffusion and void formation in CdTe1-xSex and CdTe layers. Acs Applied Materials and Interfaces 2020; 12(34): 38070–38075. Becerril-Romero I, Sylla D, Placidi M, et al. Transition-metal oxides for kesterite solar cells developed on transparent substrates. Acs Applied Materials and Interfaces 2020; 12(30): 33656. Kim B, Park GS, Kim JH, et al. Boosting solar cell performance via centrally localized Ag in solution-processed Cu(In,Ga)(S,Se)2 thin film solar cells. Acs Applied Materials and Interfaces 2020; 12(32): 36082–36091. Shi XN, Wang YX, Yu H, et al. Significantly improving the crystal growth of a Cu2ZnSn(S,Se)4 absorber layer by air-annealing a Cu2ZnSnS4 precursor thin film. Acs Applied Materials and Interfaces 2020; 12(37): 41590–41595. Song YP, Sun HH, Yao B, et al. Modulation of field-effect passivation at the back electrode interface enabling efficient kesterite-type Cu2ZnSn(S,Se)4 thin-film solar cells. Acs Applied Materials and Interfaces 2020; 12(34): 38163–38174. Feng JJ, Ma XH, Liao J, et al. A potential alternative deposition technology for CdS buffer layer in kesterite solar cells via intermittent photochemical deposition. Applied Surface Science 2020; 527: 146911. Lu XS, Xu B, Ma CH, et al. Improving the efficiency of Cu2ZnSnS4 solar cells by promoting the homogeneous distribution of Sn element. Applied Surface Science 2020; 529: 147160. Zandi S, Saxena P, Razaghi M, et al. Simulation of CZTSSe thin-film solar cells in COMSOL: Three-dimensional optical, electrical, and thermal models. IEEE Journal of Photovoltaics 2020; 10(5): 1503–1507. Zheng X, Colegrove E, Duenow JN, et al. Roles of bandgrading, lifetime, band alignment, and carrier concentration in high-efficiency CdSeTe solar cells. Journal of Applied Physics 2020; 128(5): 053102. Park J, Yoo H, Karade V, et al. Investigation of low intensity light performances of kesterite CZTSe, CZTSSe, and CZTS thin film solar cells for indoor applications. Journal of Materials Chemistry A 2020; 8(29): 14538–14544. Shi XN, Huang LJ, Pan DC. Ionic liquid-assisted green solution approach for high-performance Cu2ZnSn(S,Se)4 thin film solar cells. Journal of Power Sources 2020; 473: 228529. Li DB, Bista SS, Song ZN, et al. Maximize CdTe solar cell performance through copper activation engineering. Nano Energy 2020; 73: 104835. Yu Q, Shi JJ, Guo LB, et al. Eliminating multi-layer crystallization of Cu2ZnSn(S,Se)4 absorber by controlling back interface reaction. Nano Energy 2020; 76: 105042. Krause M, Nikolaeva A, Maiberg M, et al. Microscopic origins of performance losses in highly efficient Cu (In,Ga)Se2 thin-film solar cells. Nature Communications 2020; 11(1): 4189. Durmusoglu EG, Selopal GS, Mohammadnezhad M, et al. Low-cost, air-processed quantum dot solar cells via diffusion-controlled synthesis. Acs Applied Materials and Interfaces 2020; 12(32): 36301–36310. Georgitzikis E, Genoe J, Heremans P, et al. Carrier mobility, lifetime, and diffusion length in optically thin quantum dot semiconductor films. Acs Applied Materials and Interfaces 2020; 12(27): 30565–30571. Yang XK, Yang J, Ullah MI, et al. Enhanced passivation and carrier collection in ink-processed PbS quantum dot solar cells via a supplementary ligand strategy. Acs Applied Materials and Interfaces 2020; 12(37): 42217–42225. Chiu A, Rong E, Bambini C, et al. Sulfur-infused hole transport materials to overcome performance-limiting transport in colloidal quantum dot solar cells. Acs Energy Letters 2020; 5(9): 2897–2904. Solis OE, Rivas JM, Lopez-Luke T, et al. Synthesis of alloyed CdxZn1-xS quantum dots for photovoltaic applications. IEEE Journal of Photovoltaics 2020; 10(5): 1319–1328. Sun B, Johnston A, Xu C, et al. Monolayer Perovskite bridges enable strong quantum dot coupling for efficient solar cells. Joule 2020; 4(7): 1542–1556. Zhao CY, Tian WM, Sun Q, et al. Trap-enabled long-distance carrier transport in perovskite quantum wells. Journal of the American Chemical Society 2020; 142(35): 15091–15097. Choi MJ, de Arquer FPG, Proppe AH, et al. Cascade surface modification of colloidal quantum dot inks enables efficient bulk homojunction photovoltaics. Nature Communications 2020; 11(1): 103. Lee S, Choi MJ, Sharma G, et al. Orthogonal colloidal quantum dot inks enable efficient multilayer optoelectronic devices. Nature Communications 2020; 11(1): 4814. Abenante L, De Lia F, Schioppo R, et al. Non-linear continuous analytical model for performance degradation of photovoltaic module arrays as a function of exposure time. Applied Energy 2020; 275: 115363. Patel MT, Vijayan RA, Asadpour R, et al. Temperature-dependent energy gain of bifacial PV farms: A global perspective. Applied Energy 2020; 276: 115405. Zimmerman R, Panda A, Bulovic V. Techno-economic assessment and deployment strategies for vertically-mounted photovoltaic panels. Applied Energy 2020; 276: 115149. Adar M, Najih Y, Gouskir M, et al. Three PV plants performance analysis using the principal component analysis method. Energy 2020; 207: 118315. Toledo C, Lopez-Vicente R, Abad J, et al. Thermal performance of PV modules as building elements: Analysis under real operating conditions of different technologies. Energy and Buildings 2020; 223: 110087. Buresh KM, Apperley MD, Booysen MJ. Three shades of green: Perspectives on at-work charging of electric vehicles using photovoltaic carports. Energy for Sustainable Development 2020; 57: 132–140. Arslanoglu N, Yigit A, Eker BS. Investigation of wind speed effect on different mounted PV systems using satellite data. Environmental Progress and Sustainable Energy 2020; 39(4): e13397. Gok A, Ozkalay E, Friesen G, et al. The influence of operating temperature on the performance of BIPV modules. IEEE Journal of Photovoltaics 2020; 10(5): 1371–1378. Jamil WJ, Rahman HA, Shaari S, et al. Modeling of soiling derating factor in determining photovoltaic outputs. IEEE Journal of Photovoltaics 2020; 10(5): 1417–1423. Li CX, Spataru SV, Zhang KJ, et al. A multi-state dynamic thermal model for accurate photovoltaic cell temperature estimation. IEEE Journal of Photovoltaics 2020; 10(5): 1465–1473. Rodriguez-Gallegos CD, Gandhi O, Panda SK, et al. On the PV tracker performance: Tracking the sun versus tracking the best orientation. IEEE Journal of Photovoltaics 2020; 10(5): 1474–1480. Schulze A, Koentopp MB, Taubitz C. A drift and diffusion model for PID-s in solar modules. IEEE Journal of Photovoltaics 2020; 10(5): 1403–1408. Mohammed MS, Vural RA. Evolutionary design automation of high efficiency series resonant converter for photovoltaic systems. IEEE Transactions on Power Electronics 2020; 35(11): 11332–11343. Yingying Z, Dongsheng L, Tun L, et al. Collaborative fault detection for large-scale photovoltaic systems. IEEE Transactions on Sustainable Energy 2020; 11(4): 2745. Agbulut U, Gurel AE, Ergun A, et al. Performance assessment of a V-trough photovoltaic system and prediction of power output with different machine learning algorithms. Journal of Cleaner Production 2020; 268: 122269. D'Adamo I, Falcone PM, Gastaldi M, et al. The economic viability of photovoltaic systems in public buildings: Evidence from Italy. Energy 2020; 207: 118316. Zhang MH, Zhang Q. Grid parity analysis of distributed photovoltaic power generation in China. Energy 2020; 206: 118165. Do TN, Burke PJ, Baldwin KGH, et al. Underlying drivers and barriers for solar photovoltaics diffusion: The case of Vietnam. Energy Policy 2020; 144: 111561. Sreenath S, Sudhakar K, Yusop AF. Solar photovoltaics in airport: Risk assessment and mitigation strategies. Environmental Impact Assessment Review 2020; 84: 106418. Liu MZ, Procopiou AT, Petrou K, et al. On the fairness of PV curtailment schemes in residential distribution networks. IEEE Transactions on Smart Grid 2020; 11(5): 4502–4512. Biyuan L, Lei W, Qinghua W. Maximum power point scanning for PV systems under various partial shading conditions. IEEE Transactions on Sustainable Energy 2020; 11(4): 2556. Rodriguez-Gallegos CD, Liu HH, Gandhi O, et al. Global techno-economic performance of bifacial and tracking photovoltaic systems. Joule 2020; 4(7): 1514–1541.