39 results on '"Maikel F.A.M. van Hest"'
Search Results
2. Improving Low-Bandgap Tin–Lead Perovskite Solar Cells via Contact Engineering and Gas Quench Processing
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Maikel F.A.M. van Hest, Joseph J. Berry, Michael D. McGehee, Eli J. Wolf, Axel F. Palmstrom, Isaac E. Gould, Tyler A. Gossett, Taylor Moot, Joseph M. Luther, Jérémie Werner, and Caleb C. Boyd
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Materials science ,Renewable Energy, Sustainability and the Environment ,Band gap ,Photovoltaic system ,Energy Engineering and Power Technology ,chemistry.chemical_element ,Hole transport layer ,02 engineering and technology ,010402 general chemistry ,021001 nanoscience & nanotechnology ,01 natural sciences ,Maximum power point tracking ,0104 chemical sciences ,Fuel Technology ,Chemical engineering ,PEDOT:PSS ,chemistry ,Chemistry (miscellaneous) ,Materials Chemistry ,Power output ,0210 nano-technology ,Tin ,Perovskite (structure) - Abstract
Low-bandgap Sn/Pb ABX3 perovskites have reached photovoltaic power conversion efficiencies >20%, but they usually have poor stability due to the common use of acidic poly(3,4-ethylenedioxythiophene...
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- 2020
3. Three-terminal III–V/Si tandem solar cells enabled by a transparent conductive adhesive
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Robby Peibst, Paul Stradins, Bill Nemeth, Adele C. Tamboli, Henning Schulte-Huxel, John F. Geisz, Paul F. Ndione, Talysa R. Klein, Maikel F.A.M. van Hest, Emily L. Warren, Manuel Schnabel, and Michael Rienäcker
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010302 applied physics ,Materials science ,Tandem ,Equivalent series resistance ,Renewable Energy, Sustainability and the Environment ,Solar spectra ,business.industry ,Energy Engineering and Power Technology ,02 engineering and technology ,021001 nanoscience & nanotechnology ,01 natural sciences ,law.invention ,Fuel Technology ,Terminal (electronics) ,law ,0103 physical sciences ,Solar cell ,Optoelectronics ,Adhesive ,0210 nano-technology ,business ,Electrical conductor ,Electronic circuit - Abstract
Tandem or multijunction solar cells are able to convert sunlight to electricity with greater efficiency than single junction solar cells by splitting the solar spectrum across sub-cells with different bandgaps. With the efficiencies of many common single-junction solar cell materials leveling off near their theoretical efficiency limits, there is renewed interest in applying this approach. However, there is ongoing debate as to the best approach for interconnecting sub-cells in series, or whether it is preferable to operate them independently. In this paper, we provide the first experimental demonstration of a tandem cell architecture with three terminals: one on top of the tandem cell, and two beneath it, in interdigitated back contact configuration. The two cells are interconnected with a transparent conductive adhesive, which is compatible with rough surfaces and exhibits negligible series resistance. Combining GaInP and Si sub-cells in this manner allows us to achieve a GaInP/Si tandem cell with a two-terminal efficiency of 26.4 ± 1.0%. We then show that utilizing all three terminals results in an efficiency boost of 0.9 ± 0.2%, to an efficiency of 27.3 ± 1.0%, and discuss the operation of the cell and its two interacting circuits.
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- 2020
4. Carrier gradients and the role of charge selective contacts in lateral heterojunction all back contact perovskite solar cells
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Kai Zhu, Jean-Baptiste Puel, Sean P. Dunfield, Vincent Dufoulon, Glenn Teeter, Rosemary C. Bramante, Mathieu Frégnaux, Fei Zhang, Joseph J. Berry, Talysa R. Klein, Jean-Paul Kleider, Muriel Bouttemy, Joseph M. Luther, Davide Regaldo, Dennis Nordlund, Stefania Cacovich, Maikel F.A.M. van Hest, Aleksandra Bojar, David T. Moore, Philip Schulz, National Renewable Energy Laboratory, Golden, Institut Photovoltaïque d’Ile-de-France (ITE) (IPVF), Laboratoire Génie électrique et électronique de Paris (GeePs), CentraleSupélec-Sorbonne Université (SU)-Université Paris-Saclay-Centre National de la Recherche Scientifique (CNRS), Institut Lavoisier de Versailles (ILV), Université de Versailles Saint-Quentin-en-Yvelines (UVSQ)-Institut de Chimie du CNRS (INC)-Centre National de la Recherche Scientifique (CNRS), SLAC National Accelerator Laboratory (SLAC), and Stanford University
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Materials science ,Photoemission spectroscopy ,Surface photovoltage ,QC1-999 ,contact selectivity ,General Physics and Astronomy ,02 engineering and technology ,010402 general chemistry ,7. Clean energy ,01 natural sciences ,perovskite solar cells ,[SPI]Engineering Sciences [physics] ,X-ray photoelectron spectroscopy ,lateral heterojunction ,[CHIM]Chemical Sciences ,General Materials Science ,ComputingMilieux_MISCELLANEOUS ,Perovskite (structure) ,Kelvin probe force microscope ,[PHYS]Physics [physics] ,X-ray absorption spectroscopy ,photoemission spectroscopy ,business.industry ,Physics ,General Engineering ,Heterojunction ,General Chemistry ,021001 nanoscience & nanotechnology ,0104 chemical sciences ,Active layer ,General Energy ,Optoelectronics ,0210 nano-technology ,business ,carrier concentration - Abstract
Summary Realizing photovoltaic devices that achieve the full potential of the metal halide perovskite material will require improved insight regarding the role of selective contacts and how key interfaces operate when mobile defects are present. However, measuring interface properties in typical device stacks where the perovskite layer is thin and sandwiched between two contacts has been a challenge. Here, we fabricate p-i-n and p-n lateral heterojunctions with nickel oxide/titanium oxide all back contacts, permitting us to employ a comprehensive analysis approach, including ultraviolet and X-ray photoemission spectroscopy (UPS/XPS), angle-resolved X-ray absorption spectroscopy (XAS), Kelvin probe force microscopy (KPFM), surface photovoltage (SPV), hyperspectral imaging (HSI), and time-resolved fluorescence lifetime imaging microscopy (TR-FLIM) to discern the role of selective contacts. Specifically, we tune the selectivity of the contacts, changing the gradient in the carrier concentration across the surface of the active layer, which is connected to carrier extraction at the buried interface, and thus the device functionality.
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- 2021
5. Enabling Flexible All-Perovskite Tandem Solar Cells
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Bobby To, Severin N. Habisreutinger, Matthew O. Reese, Maikel F.A.M. van Hest, Joseph J. Berry, Jun Liu, Jérémie Werner, David T. Moore, Giles E. Eperon, Steven T. Christensen, Rohit Prasanna, Joseph M. Luther, Tomas Leijtens, Taylor Moot, E. Ashley Gaulding, Michael D. McGehee, Sanjini U. Nanayakkara, Sean P. Dunfield, Axel F. Palmstrom, and William Nemeth
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chemistry.chemical_classification ,Fabrication ,Materials science ,Tandem ,business.industry ,Energy conversion efficiency ,Nucleation ,Wide-bandgap semiconductor ,02 engineering and technology ,Polymer ,010402 general chemistry ,021001 nanoscience & nanotechnology ,01 natural sciences ,0104 chemical sciences ,Atomic layer deposition ,General Energy ,chemistry ,Optoelectronics ,0210 nano-technology ,business ,Voltage - Abstract
Summary Multijunction all-perovskite solar cells offer a route toward efficiencies of III-V materials at low cost by combining the advantages of low thermalization loss in multijunction architectures with the beneficial properties of perovskites—namely, low processing cost, high-throughput fabrication, and compatibility with flexible substrates. However, there are two main challenges for enabling high-efficiency tandems: (1) design of a recombination layer to efficiently combine two perovskite subcells while also preventing bottom cell damage during top cell processing and (2) achieving high open-circuit voltage of the wide-gap subcell. Herein, we overcome both of these challenges. First, we demonstrate a nucleation layer consisting of an ultra-thin polymer with nucleophilic hydroxyl and amine functional groups for nucleating a conformal, low-conductivity aluminum zinc oxide layer by atomic layer deposition (ALD). This method enables ALD-grown recombination layers that reduce shunting as well as solvent degradation from solution processing on top of existing perovskite active layers. Next, we demonstrate a band-gap tuning strategy based on A-site cations of mismatched size (dimethylammonium and cesium) to enable a 1.7 eV perovskite with high, stable voltages. By combining these advances, we fabricate two-terminal all-perovskite tandem solar cells with 23.1% power conversion efficiency on rigid substrates and 21.3% on flexible plastic substrates.
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- 2019
6. Measurement of band offsets and shunt resistance in CdTe solar cells through temperature and intensity dependence of open circuit voltage and photoluminescence
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Mark Holtz, Matthew O. Reese, C. H. Swartz, Sadia R. Rab, Joseph M. Luther, T. H. Myers, Jian V. Li, Maikel F.A.M. van Hest, Yanfa Yan, Deng-Bing Li, E. G. LeBlanc, Benjia Dou, Sandip S. Bista, Sanjoy Paul, Corey R. Grice, and Gregory F. Pach
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Photoluminescence ,Materials science ,Renewable Energy, Sustainability and the Environment ,Open-circuit voltage ,business.industry ,020209 energy ,Photoconductivity ,Photovoltaic system ,02 engineering and technology ,021001 nanoscience & nanotechnology ,Cadmium telluride photovoltaics ,0202 electrical engineering, electronic engineering, information engineering ,Optoelectronics ,General Materials Science ,0210 nano-technology ,business ,Ohmic contact ,Excitation ,Shunt (electrical) - Abstract
Band offsets at the back contact and front window layer in CdTe-based solar cells affect photovoltaic performance and challenge standard characterization methods. By analyzing the temperature and excitation dependence of both open circuit voltage and absolute photoluminescence intensity, we show that the effects band offsets can be separated from the effects of recombination and shunting. Solar cells were grown with MgZnO window layers and compared to cells with CdS window layers containing varying amounts of oxygen. It was demonstrated that band alignment rather than reduced recombination velocity is the reason for the success of MgZnO as a front interface contact. An assortment of thin back contact interlayers were also deposited, and a PbTe interlayer showed some promise as an Ohmic contact to the CdTe, though it appears to induce a photoconductive shunt. Finally, we show that the shunting resistance given by a standard current-voltage curve technique generally does not represent a physically meaningful quantity unless it is well below one kiloOhm square cm.
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- 2019
7. Bimolecular Additives Improve Wide-Band-Gap Perovskites for Efficient Tandem Solar Cells with CIGS
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Bryon W. Larson, Stephen Glynn, Christopher P. Muzzillo, Yanfa Yan, Dong Hoe Kim, Haipeng Lu, Chungseok Choi, Jinhui Tong, James B. Whitaker, Yu Huang, Steven P. Harvey, Zhen Li, Maikel F.A.M. van Hest, Lorelle M. Mansfield, Axel F. Palmstrom, Joseph J. Berry, Kai Zhu, and Fei Zhang
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Electron mobility ,Materials science ,Tandem ,business.industry ,Wide-bandgap semiconductor ,Perovskite solar cell ,02 engineering and technology ,Carrier lifetime ,010402 general chemistry ,021001 nanoscience & nanotechnology ,01 natural sciences ,Copper indium gallium selenide solar cells ,0104 chemical sciences ,Crystallinity ,General Energy ,Optoelectronics ,0210 nano-technology ,business ,Perovskite (structure) - Abstract
Summary Tandem solar cells coupling narrow- and wide-band-gap thin-film polycrystalline absorbers are attractive for achieving ultrahigh efficiency with low manufacturing cost. For established narrow-band-gap CIGS thin-film bottom cells, a challenge is to develop highly efficient polycrystalline wide-band-gap top cells. Here, we demonstrate a 1.68-eV (FA0.65MA0.20Cs0.15)Pb(I0.8Br0.2)3 wide-band-gap perovskite solar cell with an efficiency of ∼20% enabled by using PEAI and Pb(SCN)2 complementary additives in the perovskite precursor. The coupling of PEA+ and SCN− provides a synergistic effect that overcomes growth challenges with either additive individually and improves perovskite film quality with enhanced crystallinity, reduced formation of excess PbI2 (in comparison to using Pb(SCN)2 additive alone), lower defect density and energetic disorder, and an improved carrier mobility (∼47 cm2 V−1s−1) and lifetime (∼2.9 μs). When coupling a semi-transparent 1.68-eV perovskite top cell fabricated by this approach with a 1.12-eV CIGS bottom cell, we achieve 25.9%-efficient polycrystalline perovskite/CIGS 4-terminal thin-film tandem solar cells.
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- 2019
8. A novel blanket annealing process to achieve highly transparent and conducting Al doped ZnO thin films: Its mechanism and application in perovskite solar cells
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Sean M. Garner, Arindam Mallick, Shuvaraj Ghosh, Maikel F.A.M. van Hest, Durga Basak, and Benjia Dou
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010302 applied physics ,Materials science ,Renewable Energy, Sustainability and the Environment ,business.industry ,Annealing (metallurgy) ,Doping ,Oxide ,02 engineering and technology ,021001 nanoscience & nanotechnology ,01 natural sciences ,chemistry.chemical_compound ,chemistry ,Electrical resistivity and conductivity ,0103 physical sciences ,Electrode ,Optoelectronics ,Figure of merit ,General Materials Science ,Thin film ,0210 nano-technology ,business ,Sheet resistance - Abstract
Achievement of high conductivity by doping an oxide thin film while maintaining its high visible transparency remains a challenge in the field of materials science and technology. Here, we demonstrate a simple and novel technique to control compensating defects in Al doped ZnO (AZO) thin films involving a post-growth annealing process with Zn blanket. We also provide an in-depth understanding of the mechanism of achieving high conductivity. As low as 8.8 Ω/sq sheet resistance (resistivity 3.1 × 10−4 Ω cm) with 90% visible transmission value and wherefrom a figure of merit (FOM) value of 6.5 × 10−2 Ω−1 for a RF sputtered 350 nm AZO thin film can be achieved. Such very low sheet resistance has been attributed to a decrease in the number of compensating defects and lesser out diffusion of Zn in AZO. Application of the developed AZO film as conducting substrate has successfully been tested by fabricating perovskite solar cells on flexible Corning® Willow® Glass substrate. The present findings open up the possibility of enough high quality industrial-scale production of transparent conducting oxides (TCOs) bearing crucial significance from the perspective of transparent electrodes for solar cells.
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- 2018
9. Scalable Fabrication of Perovskite Solar Cells to Meet Climate Targets
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Yu-Ying Lin, John Simonaitis, Christopher J. Tassone, Benjia Dou, Karsten Bruening, and Maikel F.A.M. van Hest
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Fabrication ,Materials science ,Photovoltaic system ,Energy conversion efficiency ,02 engineering and technology ,010402 general chemistry ,021001 nanoscience & nanotechnology ,01 natural sciences ,Engineering physics ,0104 chemical sciences ,law.invention ,General Energy ,Rapid thermal processing ,law ,Solar cell ,Thin film ,0210 nano-technology ,Cost of electricity by source ,Perovskite (structure) - Abstract
Summary Cost modeling shows that high-throughput processing of perovskite solar cells is required not only to compete with incumbent technologies in terms of levelized cost of energy, but more importantly, it is the major enabling factor facilitating sustainable growth rates of solar cell manufacturing capacity commensurate with global climate targets. We performed rapid thermal annealing at blade-coating speed to quickly deposit and convert perovskite thin films for scalable manufacturing of perovskite solar cells. In situ X-ray diffraction during film deposition and thermal conversion gave insight into the formation of crystalline intermediates, essential for high-quality films. Parameters were optimized based on the in situ study, allowing perovskite films to be annealed within 3 s with a champion power conversion efficiency of 16.8%. This opens up a clear pathway toward industrial-scale high-throughput manufacturing, which is required to fulfill the projected photovoltaic installation rates needed to reach climate goals.
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- 2018
10. Fabrication of Flexible Perovskite Solar Cells via Rapid Thermal Annealing
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Maikel F.A.M. van Hest, Thad Druffel, Blake Martin, and Mengjin Yang
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Fabrication ,Materials science ,business.industry ,Annealing (metallurgy) ,Photovoltaic system ,02 engineering and technology ,010402 general chemistry ,021001 nanoscience & nanotechnology ,01 natural sciences ,0104 chemical sciences ,Optoelectronics ,Temperature sensitive ,Thin film ,Rapid thermal annealing ,0210 nano-technology ,business ,Electrical conductor ,Perovskite (structure) - Abstract
Perovskite thin films are currently fabricated via solution-processible methods that rapidly deposit perovskite inks; however, annealing perovskite thin films remains a bottleneck in the manufacturing process. A combination of different methods to reduce requisite time for perovskite film formation while simultaneously protecting temperature sensitive plastic substrates are needed to make flexible PSCs at scale. Here, we introduce a blade coated perovskite thin film annealed via a two-step staggered rapid thermal annealing (RTA) for 7 seconds yielding PSCs with a PCE of 14.6% on flexible ITO/PET. This study demonstrates the advantages of RTA over conventional conductive annealing when manufacturing temperature-sensitive, flexible PSCs.
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- 2020
11. Blade-Coated Electron Transport Layers to Enable Scalable Perovskite Photovoltaics
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David P. Ostrowski, Keith P. Moran, Maikel F.A.M. van Hest, Mengjin Yang, and Kyle J. Reiter
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Materials science ,Fullerene ,business.industry ,Perovskite solar cell ,02 engineering and technology ,engineering.material ,010402 general chemistry ,021001 nanoscience & nanotechnology ,01 natural sciences ,Cathode ,0104 chemical sciences ,law.invention ,Hysteresis ,Coating ,Photovoltaics ,law ,engineering ,Optoelectronics ,0210 nano-technology ,business ,Layer (electronics) ,Perovskite (structure) - Abstract
With the rapid improvements in performance of perovskite photovoltaics, scale represents one of the few remaining hurdles to commercial viability. The active perovskite layer has previously been deposited via a scalable solution-based method, blade coating. Associated transport layers, however, are often deposited using energy- and capital-intensive methods. Here, we present processes by which the electron transport layer, a mixed fullerene solution, and cathode buffer layer, bathocuproine, are blade-coated in an ambient environment to fabricate large-area solar devices that match or outperform the equivalent film deposited via thermal evaporation. With this work, a high-performing, scalable perovskite solar cell can be manufactured in ambient conditions from top to bottom contact.
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- 2020
12. Roll-to-Roll Printing of Perovskite Solar Cells
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David T. Moore, John Ryter, Frank S. Barnes, Karsten Bruening, Maikel F.A.M. van Hest, Lance M. Wheeler, Kai Zhu, James B. Whitaker, Sean M. Garner, Christopher J. Tassone, Joseph J. Berry, Nicholas J. Breslin, Sean E. Shaheen, and Benjia Dou
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Materials science ,Renewable Energy, Sustainability and the Environment ,business.industry ,Photovoltaic system ,Energy conversion efficiency ,Energy Engineering and Power Technology ,Halide ,02 engineering and technology ,engineering.material ,010402 general chemistry ,021001 nanoscience & nanotechnology ,01 natural sciences ,0104 chemical sciences ,Roll-to-roll processing ,Crystallinity ,Fuel Technology ,Coating ,Chemistry (miscellaneous) ,Materials Chemistry ,engineering ,Optoelectronics ,Texture (crystalline) ,0210 nano-technology ,business ,Perovskite (structure) - Abstract
High efficiency combined with transformative roll-to-roll (R2R) printability makes metal halide perovskite-based solar cells the most promising solar technology to address the terawatt challenge of the future energy demand. However, translation from lab-scale deposition solution processing techniques to large-scale R2R methods has typically led to reduced photovoltaic performance. Here, we demonstrate large-scale, highly crystalline, uniaxially oriented, smooth perovskite films printed at room temperature and in the ambient environment. Confirmed with high speed in situ X-ray diffraction measurements, the perovskite films reach 98% of relative crystallinity at room temperature and display high texture within 1 s of the coating. We demonstrate an all-blade-coated metal halide perovskite cell with power conversion efficiency (PCE) up to 19.6%, a slot-die coated cell with a PCE of 17.3%, and a partially R2R slot-die coated flexible glass-based cell efficiency of 14.1%. The developed printing method can be ap...
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- 2018
13. Outlook and Challenges of Perovskite Solar Cells toward Terawatt-Scale Photovoltaic Module Technology
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Kai Zhu, Dong Hoe Kim, James B. Whitaker, Maikel F.A.M. van Hest, and Zhen Li
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Fabrication ,Computer science ,Scale (chemistry) ,Photovoltaic system ,02 engineering and technology ,010402 general chemistry ,021001 nanoscience & nanotechnology ,01 natural sciences ,Engineering physics ,0104 chemical sciences ,General Energy ,Software deployment ,0210 nano-technology ,Perovskite (structure) - Abstract
Rapid development of perovskite solar cells (PSCs) during the past several years has made this photovoltaic (PV) technology a serious contender for potential large-scale deployment on the terawatt scale in the PV market. To successfully transition PSC technology from the laboratory to industry scale, substantial efforts need to focus on scalable fabrication of high-performance perovskite modules with minimum negative environmental impact. Here, we provide an overview of the current research and our perspective regarding PSC technology toward future large-scale manufacturing and deployment. Several key challenges discussed are (1) a scalable process for large-area perovskite module fabrication; (2) less hazardous chemical routes for PSC fabrication; and (3) suitable perovskite module designs for different applications.
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- 2018
14. Synthesis of CZTS/Se and Their Solid Solution from Electrodeposited Cu–Sn–Zn Metal Precursor: A Study of S and Se Replacement Reaction
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Manoj Neergat, Balasubramaniam Kavaipatti, Garima Aggarwal, Talysa R. Klein, Rajiv Kumar Singh, Maikel F.A.M. van Hest, Chandan Das, and Ashish Singh
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Materials science ,Band gap ,Annealing (metallurgy) ,Chalcogenide ,Energy Engineering and Power Technology ,02 engineering and technology ,010402 general chemistry ,021001 nanoscience & nanotechnology ,01 natural sciences ,0104 chemical sciences ,Metal ,chemistry.chemical_compound ,Crystallinity ,chemistry ,Chemical engineering ,visual_art ,Materials Chemistry ,Electrochemistry ,visual_art.visual_art_medium ,Chemical Engineering (miscellaneous) ,CZTS ,Single displacement reaction ,Electrical and Electronic Engineering ,0210 nano-technology ,Solid solution - Abstract
Selenization, sulfurization, and sulfo-selenization of electrodeposited metal precursor (Cu–Sn–Zn) at high temperature (500–600 °C) in S, Se, or S + Se (mixed) atmospheres are used to understand the thermodynamics of chalcogenide incorporation reaction. Phase-pure CZTSe and CZTS were obtained after annealing at 500 °C for 1 min in Se (selenization) and 600 °C for 10 min in S (sulfurization) atmospheres, respectively. CZTSSe solid solutions are synthesized by the sequential annealing of metal precursors in S and Se atmosphere separately or in the mixed (S + Se) atmosphere. In the S-rich mixed atmosphere, S-rich CZTSSe solid solution is formed at all annealing conditions. Surprisingly, in a Se-rich mixed atmosphere, longer annealing at 600 °C yields S-rich CZTSSe. The CZTSSe film formed by annealing in near equimolar S/Se atmosphere exhibits a compositional gradient across the thickness. These results suggest that the crystallinity, composition, and hence the bandgap of CZTSSe can be precisely controlled by...
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- 2018
15. Curtailing Perovskite Processing Limitations via Lamination at the Perovskite/Perovskite Interface
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Sean P. Dunfield, David M. Fabian, Maikel F.A.M. van Hest, Jeffrey A. Christians, Benjia Dou, David T. Moore, Sean E. Shaheen, Alex Dixon, Joseph J. Berry, Matthew C. Beard, Shane Ardo, and Talysa R. Klein
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Materials science ,Absorption spectroscopy ,Oxide ,Energy Engineering and Power Technology ,02 engineering and technology ,010402 general chemistry ,01 natural sciences ,law.invention ,chemistry.chemical_compound ,law ,Lamination ,Materials Chemistry ,Perovskite (structure) ,Transparent conducting film ,Equivalent series resistance ,Renewable Energy, Sustainability and the Environment ,business.industry ,021001 nanoscience & nanotechnology ,0104 chemical sciences ,Fuel Technology ,chemistry ,Chemistry (miscellaneous) ,Optoelectronics ,Quantum efficiency ,0210 nano-technology ,business ,Layer (electronics) - Abstract
Standard layer-by-layer solution processing methods constrain lead–halide perovskite device architectures. The layer below the perovskite must be robust to the strong organic solvents used to form the perovskite while the layer above has a limited thermal budget and must be processed in nonpolar solvents to prevent perovskite degradation. To circumvent these limitations, we developed a procedure where two transparent conductive oxide/transport material/perovskite half stacks are independently fabricated and then laminated together at the perovskite/perovskite interface. Using ultraviolet–visible absorption spectroscopy, external quantum efficiency, X-ray diffraction, and time-resolved photoluminesence spectroscopy, we show that this procedure improves photovoltaic properties of the perovskite layer. Applying this procedure, semitransparent devices employing two high-temperature oxide transport layers were fabricated, which realized an average efficiency of 9.6% (maximum: 10.6%) despite series resistance l...
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- 2018
16. Degradation of Highly Alloyed Metal Halide Perovskite Precursor Inks: Mechanism and Storage Solutions
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David T. Moore, Maikel F.A.M. van Hest, Steven P. Harvey, Joseph J. Berry, Lance M. Wheeler, Frank S. Barnes, Jeffrey A. Christians, Sean E. Shaheen, and Benjia Dou
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chemistry.chemical_classification ,Renewable Energy, Sustainability and the Environment ,Iodide ,Inorganic chemistry ,Energy Engineering and Power Technology ,Halide ,02 engineering and technology ,010402 general chemistry ,021001 nanoscience & nanotechnology ,01 natural sciences ,0104 chemical sciences ,Metal ,chemistry.chemical_compound ,Fuel Technology ,Formamidinium ,chemistry ,Chemistry (miscellaneous) ,Bromide ,visual_art ,Materials Chemistry ,visual_art.visual_art_medium ,Dimethylformamide ,0210 nano-technology ,Stoichiometry ,Perovskite (structure) - Abstract
Whereas the promise of metal halide perovskite (MHP) photovoltaics (PV) is that they can combine high efficiency with solution-processability, the chemistry occurring in precursor inks is largely unexplored. Herein, we investigate the degradation of MHP solutions based on the most widely used solvents, dimethylformamide (DMF) and dimethyl sulfoxide (DMSO). For the MHP inks studied, which contain formamidinium (FA+), methylammonium (MA+), cesium (Cs+), lead (Pb2+), bromide (Br–), and iodide (I–), dramatic compositional changes are observed following storage of the inks in nitrogen in the dark. We show that hydrolysis of DMF in the precursor solution forms dimethylammonium formate, which subsequently incorporates into the MHP film to compromise the ability of Cs+ and MA+ to stabilize FA+-based MHP. The changes in solution chemistry lead to a modification of the perovskite film stoichiometry, band gap, and structure. The solid precursor salts are stable when ball-milled into a powder, allowing for the storag...
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- 2018
17. Effect of supersonic spraying impact velocity on opto-electric properties of transparent conducting flexible films consisting of silver nanowire, ITO, and polyimide multilayers
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Sam S. Yoon, Tae Gun Kim, Min Woo Kim, Maikel F.A.M. van Hest, Dae-Hyung Cho, Yong-Duck Chung, Hong Seok Jo, Jong Gun Lee, and Chanwoo Park
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Materials science ,Scanning electron microscope ,Mechanical Engineering ,Metals and Alloys ,02 engineering and technology ,Substrate (electronics) ,010402 general chemistry ,021001 nanoscience & nanotechnology ,01 natural sciences ,0104 chemical sciences ,Indium tin oxide ,Mechanics of Materials ,Materials Chemistry ,Composite material ,0210 nano-technology ,Spectroscopy ,Deposition (law) ,Polyimide ,Sheet resistance ,Transparent conducting film - Abstract
We demonstrate the use of supersonic spraying for the deposition of silver nanowires (AgNWs) on a flexible polyimide (PI) substrate for the formation of transparent and conducting films (TCF) as an alternative to nonflexible ITO (indium tin oxide). The self-fused intersections of the NWs resulted in films with a low sheet resistance (Rs = 31 Ω/sq) and fairly high transmittance (Tr = 92%) on a glass substrate. The effect of the impact speed of the supersonically sprayed AgNWs on the opto-electric properties of the flexible TCF was evaluated by varying the spray coating conditions. The fabricated films were characterized by X-ray diffraction analysis, atomic force microscopy, ultraviolet–visible spectroscopy, and scanning electron microscopy. Finally, cyclic bending tests were performed on the PI/AgNW films as well as PI/ZnO/indium tin oxide/AgNW films, and the changes in their electrical properties with bending were compared.
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- 2018
18. Highly Efficient Perovskite Solar Modules by Scalable Fabrication and Interconnection Optimization
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Mengjin Yang, Bertrand J. Tremolet de Villers, Dong Hoe Kim, Joseph J. Berry, Talysa R. Klein, Maikel F.A.M. van Hest, Zhen Li, Matthew O. Reese, and Kai Zhu
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Interconnection ,Materials science ,Fabrication ,Renewable Energy, Sustainability and the Environment ,business.industry ,Energy Engineering and Power Technology ,Perovskite solar cell ,Schottky diode ,02 engineering and technology ,engineering.material ,010402 general chemistry ,021001 nanoscience & nanotechnology ,01 natural sciences ,0104 chemical sciences ,Fuel Technology ,Coating ,Chemistry (miscellaneous) ,Materials Chemistry ,engineering ,Optoelectronics ,0210 nano-technology ,business ,Ohmic contact ,Layer (electronics) ,Perovskite (structure) - Abstract
To push perovskite solar cell (PSC) technology toward practical applications, large-area perovskite solar modules with multiple subcells need to be developed by fully scalable deposition approaches. Here, we demonstrate a deposition scheme for perovskite module fabrication with spray coating of a TiO2 electron transport layer (ETL) and blade coating of both a perovskite absorber layer and a spiro-OMeTAD-based hole transport layer (HTL). The TiO2 ETL remaining in the interconnection between subcells significantly affects the module performance. Reducing the TiO2 thickness changes the interconnection contact from a Schottky diode to ohmic behavior. Owing to interconnection resistance reduction, the perovskite modules with a 10 nm TiO2 layer show enhanced performance mainly associated with an improved fill factor. Finally, we demonstrate a four-cell MA0.7FA0.3PbI3 perovskite module with a stabilized power conversion efficiency (PCE) of 15.6% measured from an aperture area of ∼10.36 cm2, corresponding to an a...
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- 2018
19. Scalable slot-die coating of high performance perovskite solar cells
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Bryon W. Larson, Dong Hoe Kim, Kai Zhu, Joseph J. Berry, Maikel F.A.M. van Hest, James B. Whitaker, and Fei Zhang
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Spin coating ,Materials science ,Inkwell ,Renewable Energy, Sustainability and the Environment ,business.industry ,Photovoltaic system ,Energy Engineering and Power Technology ,02 engineering and technology ,engineering.material ,010402 general chemistry ,021001 nanoscience & nanotechnology ,Solar energy ,01 natural sciences ,Die (integrated circuit) ,0104 chemical sciences ,Fuel Technology ,Coating ,engineering ,Optoelectronics ,0210 nano-technology ,business ,Layer (electronics) ,Perovskite (structure) - Abstract
Perovskite based photovoltaic devices hold the promise to greatly reduce the cost of solar energy production; however, this potential depends greatly on the ability to deposit perovskite active layers using large scale deposition methods such as slot-die coating without sacrificing efficiency. Using a perovskite precursor ink with long wet-film processing window, we demonstrate efficient perovskite solar cells based on slot-die coated perovskite layer. We found almost no difference in the photophysical and structural details of perovskite films that were deposited by spin coating to films deposited by slot-die coating. We explored various slot-die coating parameters to determine their effect on the performance of the device metrics. In addition to slot-die coating, we demonstrate the versatility of this wide wet-film processing window by fabricating perovskite solar cells with active layers deposited by spin coating, blade coating, and spray coating that all exhibited similar performance.
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- 2018
20. Radiative Thermal Annealing/in Situ X-ray Diffraction Study of Methylammonium Lead Triiodide: Effect of Antisolvent, Humidity, Annealing Temperature Profile, and Film Substrates
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Maikel F.A.M. van Hest, Michael F. Toney, Vanessa L. Pool, and Benjia Dou
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Materials science ,Annealing (metallurgy) ,General Chemical Engineering ,Energy conversion efficiency ,Inorganic chemistry ,02 engineering and technology ,General Chemistry ,010402 general chemistry ,021001 nanoscience & nanotechnology ,01 natural sciences ,0104 chemical sciences ,law.invention ,Solvent ,chemistry.chemical_compound ,chemistry ,Chemical engineering ,law ,Solar cell ,Materials Chemistry ,Radiative transfer ,Dimethylformamide ,Triiodide ,0210 nano-technology ,Perovskite (structure) - Abstract
Organic–inorganic hybrid halide perovskites are one of the most promising emerging photovoltaic materials due to their high efficiency and potentially low processing cost. Here, we present a well-controlled, manufacturing relevant annealing method, radiative thermal annealing, for the methylammonium lead triiodide (MAPbI3) films formed by a solvent engineering process, with dimethylformamide (DMF) and dimethyl sulfoxide (DMSO) as solvent and diethyl ether as the antisolvent. Radiative thermal annealing can produce high quality perovskite films, evidenced by high efficiency solar cell devices (∼18% power conversion efficiency), in a shorter time than the widely used hot plate annealing. Using in situ X-ray diffraction during the radiative annealing, we show that the role of the antisolvent is not to form an important intermediate compound (a PbI2-MAI-DMSO complex) by washing of the main solvent (DMF), but to achieve a pinhole free, uniform film of MAPbI3 with minimal intermediate compound. Importantly, we ...
- Published
- 2017
21. Thermal engineering of FAPbI3 perovskite material via radiative thermal annealing and in situ XRD
- Author
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Michael F. Toney, Maikel F.A.M. van Hest, Frank S. Barnes, Benjia Dou, I. Ahmad, Vanessa L. Pool, Talysa R. Klein-Stockert, Sean E. Shaheen, and Douglas G. Van Campen
- Subjects
Multidisciplinary ,Materials science ,Infrared ,business.industry ,Annealing (metallurgy) ,Science ,Photovoltaic system ,General Physics and Astronomy ,Mineralogy ,02 engineering and technology ,General Chemistry ,Activation energy ,010402 general chemistry ,021001 nanoscience & nanotechnology ,01 natural sciences ,General Biochemistry, Genetics and Molecular Biology ,0104 chemical sciences ,Formamidinium ,Thermal engineering ,Radiative transfer ,Optoelectronics ,0210 nano-technology ,business ,Perovskite (structure) - Abstract
Lead halide perovskites have emerged as successful optoelectronic materials with high photovoltaic power conversion efficiencies and low material cost. However, substantial challenges remain in the scalability, stability and fundamental understanding of the materials. Here we present the application of radiative thermal annealing, an easily scalable processing method for synthesizing formamidinium lead iodide (FAPbI3) perovskite solar absorbers. Devices fabricated from films formed via radiative thermal annealing have equivalent efficiencies to those annealed using a conventional hotplate. By coupling results from in situ X-ray diffraction using a radiative thermal annealing system with device performances, we mapped the processing phase space of FAPbI3 and corresponding device efficiencies. Our map of processing-structure-performance space suggests the commonly used FAPbI3 annealing time, 10 min at 170 °C, can be significantly reduced to 40 s at 170 °C without affecting the photovoltaic performance. The Johnson-Mehl-Avrami model was used to determine the activation energy for decomposition of FAPbI3 into PbI2. Processing is crucial to ensure material quality and stability in perovskite solar cells. Here, Poolet al. develop a scalable infrared annealing method and use in situXRD to map the processing phase space relative to the device efficiency. This provides a tool to determine processing requirements.
- Published
- 2017
22. Evaluating Interconnection Schemes for Semi-transparent Perovskite Mini-modules
- Author
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Maikel F.A.M. van Hest, Rosemary C. Bramante, Colin D. Bailie, Chris Eberspacher, and Timothy S. Gehan
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Interconnection ,Materials science ,Equivalent series resistance ,business.industry ,02 engineering and technology ,010402 general chemistry ,021001 nanoscience & nanotechnology ,Semi transparent ,01 natural sciences ,0104 chemical sciences ,Indium tin oxide ,Electrode ,Optoelectronics ,Degradation (geology) ,0210 nano-technology ,business ,Perovskite (structure) - Abstract
This work evaluates the critical issues surrounding P1, P2, and P3 scribing for semi-transparent perovskite module integration. We find that P1 scribing procedures are well-translated from other thin-film technologies. P2 scribing is best performed with a mechanical scribe, but remains a source of series resistance. P3 scribing is found to cause an increase in scribing dead area and a potential degradation source.
- Published
- 2019
23. III-V/Si Tandem Cells Utilizing Interdigitated Back Contact Si Cells and Varying Terminal Configurations
- Author
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Robby Peibst, Henning Schulte-Huxel, Manuel Schnabel, Jan Schmidt, Agnes Merkle, Stephanie Essigl, Talysa R. Klein, Adele C. Tamboli, Nikhil Jain, Paul Stradins, Maikel F.A.M. van Hest, Michael Rienäcker, John F. Geisz, Emily L. Warren, and Rolf Brendel
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Interconnection ,Materials science ,Silicon ,Tandem ,business.industry ,Electrical engineering ,chemistry.chemical_element ,02 engineering and technology ,Conductivity ,021001 nanoscience & nanotechnology ,01 natural sciences ,Gallium arsenide ,Indium tin oxide ,010309 optics ,chemistry.chemical_compound ,chemistry ,Quantum dot ,0103 physical sciences ,Optoelectronics ,0210 nano-technology ,business ,Electrical conductor - Abstract
Integrating wide-bandgap III- V with Si solar cells has been shown to yield higher efficiencies than Si alone: As also presented at this conference, four-terminal efficiencies exceeding 32 % have been attained. In this contribution, independent and electrically connected operation of the subcells in such tandem cells is examined. The optics of the tandem cell change significantly if a conducting interconnect, rather than an insulating glass slide, is required between the subcells. These effects are studied, and optically optimized structures for different types of tandem cell operation are presented. It is found that minimizing reflection at the conductive interface between the two cells while maintaining conductivity is the key challenge faced in such devices.
- Published
- 2019
24. Combinatorial Chemical Bath Deposition of CdS Contacts for Chalcogenide Photovoltaics
- Author
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Andriy Zakutayev, Maikel F.A.M. van Hest, Francisco Willian de Souza Lucas, Parag Bhargava, Sudhanshu Mallick, Sebastian Siol, Krishnaiah Mokurala, and Lauryn L. Baranowski
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Light ,Chalcogenide ,Cigse ,Libraries ,External Quantum Efficiency ,Nanotechnology ,Efficiency ,02 engineering and technology ,Substrate (electronics) ,Sulfides ,010402 general chemistry ,01 natural sciences ,Dip-coating ,chemistry.chemical_compound ,Electricity ,Photovoltaics ,Alloys ,Cadmium Compounds ,Solar Energy ,Devices ,Combinatorial Chemistry Techniques ,Thin film ,Of-The-Art ,In2s3 ,business.industry ,Photovoltaic system ,General Chemistry ,General Medicine ,021001 nanoscience & nanotechnology ,Solar Cells ,0104 chemical sciences ,Cztse ,Current-Voltage Characteristics ,Semiconductors ,chemistry ,Electrode ,Film Solar-Cells ,Optoelectronics ,Buffer Layer ,0210 nano-technology ,business ,Chemical bath deposition - Abstract
Contact layers play an important role in thin film solar cells, but new material development and optimization of its thickness is usually a long and tedious process. A high-throughput experimental approach has been used to accelerate the rate of research in photovoltaic (PV) light absorbers and transparent conductive electrodes, however the combinatorial research on contact layers is less common. Here, we report on the chemical bath deposition (CBD) of CdS thin films by combinatorial dip coating technique and apply these contact layers to Cu(In,Ga)Se-2 (CIGSe) and Cu2ZnSnSe4 (CZTSe) light absorbers in PV devices. Combinatorial thickness steps of CdS thin films were achieved by removal of the substrate from the chemical bath, at regular intervals of time, and in equal distance increments. The trends in the photoconversion efficiency and in the spectral response of the PV devices as a function of thickness of CdS contacts were explained with the help of optical and morphological characterization of the CdS thin films. The maximum PV efficiency achieved for the combinatorial dip-coating CBD was similar to that for the PV devices processed using conventional CBD. The results of this study lead to the conclusion that combinatorial dip-coating can be used to accelerate the optimization of PV device performance of CdS and other candidate contact layers for a wide range of emerging absorbers.
- Published
- 2016
25. Fabrication of flexible perovskite solar cells via rapid thermal annealing
- Author
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Thad Druffel, Eric Amerling, Blake Martin, Rosemary C. Bramante, Mengjin Yang, Maikel F.A.M. van Hest, and Gautam Gupta
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Materials science ,Fabrication ,business.industry ,Annealing (metallurgy) ,Mechanical Engineering ,Photovoltaic system ,Energy conversion efficiency ,Perovskite solar cell ,02 engineering and technology ,010402 general chemistry ,021001 nanoscience & nanotechnology ,Condensed Matter Physics ,01 natural sciences ,0104 chemical sciences ,Mechanics of Materials ,Optoelectronics ,General Materials Science ,Thin film ,Rapid thermal annealing ,0210 nano-technology ,business - Abstract
Adaptability, lightweight, and low cost of materials make flexible perovskite solar cells essential for the perovskite technology to breach commercial photovoltaic markets. Roll-to-roll manufacturing has great potential for high-throughput perovskite manufacturing; however, conventional annealing methods are not capable of producing flexible perovskite solar cells at scale. Conventional methods are time consuming and may compromise functionality of flexible substrates under tension. Here, we introduce a blade-coated perovskite thin film on flexible ITO-coated PET annealed via rapid thermal annealing (RTA) that reduces post-deposition processing time from ~150 s to ~14 s. Performance was not sacrificed for scalability as a perovskite solar cell was produced with a power conversion efficiency (PCE) of 14.58%.
- Published
- 2020
26. Scalable Deposition of Polycrystalline Perovskite Thin Films towards High-Efficiency and Large-Area Perovskite Photovoltaics
- Author
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James B. Whitaker, Talysa R. Klein, Joseph J. Berry, Maikel F.A.M. van Hest, Zhen Li, Dong Hoe Kim, Kai Zhu, and Benjia Dou
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Spin coating ,Materials science ,business.industry ,Perovskite solar cell ,02 engineering and technology ,Substrate (electronics) ,engineering.material ,010402 general chemistry ,021001 nanoscience & nanotechnology ,01 natural sciences ,0104 chemical sciences ,Coating ,Photovoltaics ,engineering ,Optoelectronics ,Deposition (phase transition) ,Thin film ,0210 nano-technology ,business ,Perovskite (structure) - Abstract
We report scalable deposition of perovskite thin film by blade coating and slot-die coating towards large-area perovskite solar cell and module development. We find that extending perovskite ink processing window is critical to transitioning from laboratory-scale spin coating to scalable deposition. Using blade coated perovskite thin films, we demonstrate perovskite mini-modules with efficiency near 16‥. Using slot-die coating, we show uniform deposition of perovskite thin films on substrate with area larger than 200 cm2. Using slot-diecoated perovskite thin films, we obtain perovskite solar cells with efficiency higher than14‥. Further optimization of coating conditions is expected to improve device performance comparable to those prepared by spin coating for small area devices.
- Published
- 2018
27. One-Step High-Throughput Blade Coating of Perovskite Solar Cells
- Author
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Kai Zhu, Benjia Dou, Frank S. Barnes, Maikel F.A.M. van Hest, James B. Whitaker, Sean E. Shaheen, and David T. Moore
- Subjects
Materials science ,Annealing (metallurgy) ,business.industry ,Energy conversion efficiency ,Halide ,One-Step ,02 engineering and technology ,engineering.material ,010402 general chemistry ,021001 nanoscience & nanotechnology ,01 natural sciences ,0104 chemical sciences ,Renewable energy ,Crystallinity ,Coating ,Chemical engineering ,engineering ,0210 nano-technology ,business - Abstract
A metal halide perovskite (MHP) solution was developed that is compatible with high speed (1 m min-1) one-step blade coating.MHP solar cells from the developed solution can produce power conversion efficiency over 18% in ambient environment without any addition of antisolvent, gas drying, vacuum treatment or high-temperature annealing. Careful control of the annealing temperature allows fabricating of a more stable MHP due to the increased crystallinity of the MHP film. This development on one-step, antisolvent (or similar processing) treatment free, blade coating technique paves the way for the rollto- roll production of high-efficiency MHP solar cells.
- Published
- 2018
28. Scalable fabrication of perovskite solar cells
- Author
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Dong Hoe Kim, Talysa R. Klein, Zhen Li, Joseph J. Berry, Kai Zhu, Mengjin Yang, and Maikel F.A.M. van Hest
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Materials science ,Fabrication ,business.industry ,Photovoltaic system ,02 engineering and technology ,010402 general chemistry ,021001 nanoscience & nanotechnology ,01 natural sciences ,Engineering physics ,0104 chemical sciences ,Surfaces, Coatings and Films ,Electronic, Optical and Magnetic Materials ,Characterization (materials science) ,Biomaterials ,Photovoltaics ,Scalability ,Materials Chemistry ,Deposition (phase transition) ,0210 nano-technology ,business ,Energy (miscellaneous) ,Perovskite (structure) - Abstract
Perovskite materials use earth-abundant elements, have low formation energies for deposition and are compatible with roll-to-roll and other high-volume manufacturing techniques. These features make perovskite solar cells (PSCs) suitable for terawatt-scale energy production with low production costs and low capital expenditure. Demonstrations of performance comparable to that of other thin-film photovoltaics (PVs) and improvements in laboratory-scale cell stability have recently made scale up of this PV technology an intense area of research focus. Here, we review recent progress and challenges in scaling up PSCs and related efforts to enable the terawatt-scale manufacturing and deployment of this PV technology. We discuss common device and module architectures, scalable deposition methods and progress in the scalable deposition of perovskite and charge-transport layers. We also provide an overview of device and module stability, module-level characterization techniques and techno-economic analyses of perovskite PV modules. Perovskite solar cells (PSCs) have emerged as a revolutionary class of photovoltaic technology. Here, we review recent progress and challenges in scaling up PSCs towards commercialization. We discuss several areas, including device architectures, deposition methods, scalable deposition of perovskite and charge transport layers, device stability, module-level characterization and techno-economic analyses.
- Published
- 2018
29. Transparent Conductive Adhesives for Tandem Solar Cells Using Polymer-Particle Composites
- Author
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Manuel Schnabel, Adele C. Tamboli, Maikel F.A.M. van Hest, Benjamin G. Lee, Emily L. Warren, Talysa R. Klein, and Paul Stradins
- Subjects
Materials science ,Equivalent series resistance ,02 engineering and technology ,Surface finish ,Conductivity ,010402 general chemistry ,021001 nanoscience & nanotechnology ,01 natural sciences ,0104 chemical sciences ,law.invention ,law ,Lamination ,Particle ,General Materials Science ,Adhesive ,Composite material ,0210 nano-technology ,Layer (electronics) ,Electrical conductor - Abstract
Transparent conductive adhesives (TCAs) can enable conductivity between two substrates, which is useful for a wide range of electronic devices. Here, we have developed a TCA composed of a polymer–particle blend with ethylene-vinyl acetate as the transparent adhesive and metal-coated flexible poly(methyl methacrylate) microspheres as the conductive particles that can provide conductivity and adhesion regardless of the surface texture. This TCA layer was designed to be nearly transparent, conductive in only the out-of-plane direction, and of practical adhesive strength to hold the substrates together. The series resistance was measured at 0.3 and 0.8 Ω cm2 for 8 and 0.2% particle coverage, respectively, while remaining over 92% was transparent in both cases. For applications in photovoltaic devices, such as mechanically stacked multijunction III–V/Si cells, a TCA with 1% particle coverage will have less than 0.5% power loss due to the resistance and less than 1% shading loss to the bottom cell.
- Published
- 2018
30. Measurement of Relaxation Time of Excess Carriers in Si and CIGS Solar Cells by Modulated Electroluminescence Technique
- Author
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Pradeep R. Nair, Krishnamachari L. Narsimhan, Sanchit Khatavkar, Juzer Vasi, Maikel F.A.M. van Hest, Chinna V. Kannan, Kulasekaran Muniappan, Brij M. Arora, Vijay Kumar, and Miguel A. Contreras
- Subjects
Materials science ,EFFICIENCY ,Si-HJ solar cells ,modulated electroluminescence ,02 engineering and technology ,LIFETIME ,Quantum dot solar cell ,Electroluminescence ,01 natural sciences ,SEMICONDUCTORS ,0103 physical sciences ,Materials Chemistry ,Electrical and Electronic Engineering ,relaxation time ,010302 applied physics ,CU(IN,GA)SE-2 ,business.industry ,Surfaces and Interfaces ,Frequency dependence ,021001 nanoscience & nanotechnology ,Condensed Matter Physics ,Copper indium gallium selenide solar cells ,Surfaces, Coatings and Films ,Electronic, Optical and Magnetic Materials ,frequency dependence ,CRYSTALLINE-SILICON-WAFERS ,Optoelectronics ,PHOTOLUMINESCENCE ,0210 nano-technology ,business ,CIGS solar cells - Abstract
Excess carrier lifetime plays a crucial role in determining the efficiency of solar cells. In this paper, we use the frequency dependence of inphase and quadrature components of modulated electroluminescence (MEL) to measure the relaxation time (decay) of excess carriers. The advantage of the MEL technique is that the relaxation time is obtained directly from the angular frequency at which the quadrature component peaks. It does not need knowledge of the material parameters like mobility, etc., and can be used for any finished solar cells which have detectable light emission. The experiment is easy to perform with standard electrical equipment. For silicon solar cells, the relaxation time is dominated by recombination and hence, the relaxation time is indeed the excess carrier lifetime. In contrast, for the CIGS solar cells investigated here, the relaxation time is dominated by trapping and emission from shallow minority carrier traps.
- Published
- 2018
31. High-Performance Flexible Perovskite Solar Cells on Ultrathin Glass: Implications of the TCO
- Author
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Benjia Dou, Elisa M. Miller, Arindam Mallick, Shuvaraj Ghosh, Sean M. Garner, Sean E. Shaheen, Erin M. Sanehira, Frank S. Barnes, Maikel F.A.M. van Hest, Jeffrey A. Christians, Talysa R. Klein, and Durga Basak
- Subjects
Materials science ,Photoemission spectroscopy ,Photovoltaic system ,Energy conversion efficiency ,Oxide ,chemistry.chemical_element ,Nanotechnology ,02 engineering and technology ,Substrate (electronics) ,010402 general chemistry ,021001 nanoscience & nanotechnology ,01 natural sciences ,0104 chemical sciences ,chemistry.chemical_compound ,chemistry ,General Materials Science ,Physical and Theoretical Chemistry ,0210 nano-technology ,Indium ,Perovskite (structure) ,Transparent conducting film - Abstract
For halide perovskite solar cells (PSCs) to fulfill their vast potential for combining low-cost, high efficiency, and high throughput production they must be scaled using a truly transformative method, such as roll-to-roll processing. Bringing this reality closer to fruition, the present work demonstrates flexible perovskite solar cells with 18.1% power conversion efficiency on flexible Willow Glass substrates. We highlight the importance of the transparent conductive oxide (TCO) layers on device performance by studying various TCOs. While tin-doped indium oxide (ITO) and indium zinc oxide (IZO) based PSC devices demonstrate high photovoltaic performances, aluminum-doped zinc oxide (AZO) based devices underperformed in all device parameters. Analysis of X-ray photoemission spectroscopy data shows that the stoichiometry of the perovskite film surface changes dramatically when it is fabricated on AZO, demonstrating the importance of the substrate in perovskite film formation.
- Published
- 2017
32. Perovskite ink with wide processing window for scalable high-efficiency solar cells
- Author
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Sebastian Siol, Talysa R. Klein, Matthew O. Reese, Mengjin Yang, Kai Zhu, Maikel F.A.M. van Hest, Joseph J. Berry, Zhen Li, Dong Hoe Kim, Yanfa Yan, and Obadiah G. Reid
- Subjects
Spin coating ,Materials science ,Yield (engineering) ,Inkwell ,Renewable Energy, Sustainability and the Environment ,Energy Engineering and Power Technology ,Nanotechnology ,02 engineering and technology ,engineering.material ,010402 general chemistry ,021001 nanoscience & nanotechnology ,01 natural sciences ,0104 chemical sciences ,Electronic, Optical and Magnetic Materials ,law.invention ,Grain growth ,Fuel Technology ,Coating ,law ,engineering ,Deposition (phase transition) ,Crystallization ,0210 nano-technology ,Perovskite (structure) - Abstract
Perovskite solar cells have made tremendous progress using laboratory-scale spin-coating methods in the past few years owing to advances in controls of perovskite film deposition. However, devices made via scalable methods are still lagging behind state-of-the-art spin-coated devices because of the complicated nature of perovskite crystallization from a precursor state. Here we demonstrate a chlorine-containing methylammonium lead iodide precursor formulation along with solvent tuning to enable a wide precursor-processing window (up to ∼8 min) and a rapid grain growth rate (as short as ∼1 min). Coupled with antisolvent extraction, this precursor ink delivers high-quality perovskite films with large-scale uniformity. The ink can be used by both spin-coating and blade-coating methods with indistinguishable film morphology and device performance. Using a blade-coated absorber, devices with 0.12-cm2 and 1.2-cm2 areas yield average efficiencies of 18.55% and 17.33%, respectively. We further demonstrate a 12.6-cm2 four-cell module (88% geometric fill factor) with 13.3% stabilized active-area efficiency output. Perovskite-based solar cells are often fabricated by methods that are not industrially scalable. Here, Yang et al. develop an ink formulation which gives similar devices by spin coating, the lab-scale standard, and blade coating, which is a more scalable, industry-relevant deposition method.
- Published
- 2017
33. Influence of dipping cycles on physical, optical, and electrical properties of Cu2NiSnS4: Direct solution dip coating for photovoltaic applications
- Author
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Sebastian Siol, Talysa R. Klein, Parag Bhargava, Maikel F.A.M. van Hest, Sudhanshu Mallick, and Krishnaiah Mokurala
- Subjects
Soda-lime glass ,Optoelectronic Properties ,Materials science ,Photo Response ,Annealing (metallurgy) ,Chalcogenide ,Dip Coating ,Energy-dispersive X-ray spectroscopy ,02 engineering and technology ,Substrate (electronics) ,Efficiency ,Dipping Cycles ,engineering.material ,Cu2znsns4 Thin-Films ,01 natural sciences ,Dip-coating ,Annealing ,chemistry.chemical_compound ,Coating ,0103 physical sciences ,Cu2znsn(S,Se)(4) ,Materials Chemistry ,Cu2nisns4 ,010302 applied physics ,Sulfurization ,Mechanical Engineering ,Metallurgy ,Sodium ,Metals and Alloys ,Thermal-Decomposition ,021001 nanoscience & nanotechnology ,Tin oxide ,Semiconductor Cu2msns4 M ,chemistry ,Chemical engineering ,Mechanics of Materials ,engineering ,Film Solar-Cells ,Nanoparticles ,Thermoelectric Properties ,0210 nano-technology - Abstract
Direct solution coating technique has emerged as a promising economically viable process for earth abundant chalcogenide absorber materials for photovoltaic applications. Here, direct ethanol based dip coating of earth abundant Cu2NiSnS4 (CNTS) films on soda lime glass (SLG), molybdenum coated glass (Mo), and fluorine doped tin oxide coated glass (FTO) substrates is investigated. The structural and morphological properties of pre-annealed and sulfurized CNTS films coated on SLG, FTO, and Mo substrates are reported. The influence of dipping cycles on composition and optoelectronic properties of preannealed and sulfurized CNTS films deposited on SLG substrate is presented. Energy dispersive spectroscopy (EDS) and X-ray fluorescence (XRF) analysis reveal how changes in thickness and elemental composition affect morphology and optoelectronic properties. The obtained absorption coefficient, optical bandgap, resistivity and mobility of pre -annealed and sulfurized films are found to be 104 cm(-1), 1.5 eV, 0.48 cm, 3.4 cm(2)/Vs and 104 cm(-1), 1.29 eV, 0.14 Omega cm, 11.0 cm(2)/Vs, respectively. These properties are well suited for photovoltaic applications and lead to the conclusion that the direct ethanol based dip coating can be an alternative economically viable process for the fabrication of earth abundant CNTS absorber layers for thin film solar cells. (C) 2017 Elsevier B.V. All rights reserved.
- Published
- 2017
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34. Towards All-Inorganic Transport Layers for Wide-Band Gap Formamidinium Lead Bromide-Based Planar Photovoltaics
- Author
-
Maikel F.A.M. van Hest, Neha Mahuli, Anand S. Subbiah, Sumanshu Agarwal, and Shaibal K. Sarkar
- Subjects
Materials science ,Performance ,Inorganic chemistry ,02 engineering and technology ,Efficiency ,010402 general chemistry ,Absorber ,01 natural sciences ,Electron ,Atomic layer deposition ,Degradation ,Planar ,Photovoltaics ,Ch3nh3pbi3 ,Perovskite (structure) ,business.industry ,Halide Perovskites ,Energy conversion efficiency ,Wide-bandgap semiconductor ,021001 nanoscience & nanotechnology ,Rutile Tio2 Nanorod ,0104 chemical sciences ,General Energy ,Formamidinium ,Optoelectronics ,0210 nano-technology ,business ,Layer (electronics) ,Stability ,Perovskite Solar-Cells - Abstract
Hybrid perovskite photovoltaic devices heavily rely on the use of organic (rather than inorganic) charge-transport layers on top of a perovskite absorber layer because of difficulties in depositing inorganic materials on top of these fragile absorber layers. However, in comparison to the unstable and expensive organic transport materials, inorganic charge transport layers provide improved charge transport and stability to the device architecture. Here, we report photovoltaic devices using all-inorganic transport layers in a planar p-i-n junction device configuration using formamidinium lead tribromide (FAPbBr(3)) as an absorber. Efficient planar devices are obtained through atomic layer deposition of nickel oxide and sputtered zinc oxide as hole- and electron-transport materials, respectively. Using only inorganic charge-transport layers resulted in planar FAPbBr3 devices with a power conversion efficiency of 6.75 % at an open-circuit voltage of 1.23 V. The transition of planar FAPbBr3 devices making from all-organic towards all inorganic charge-transport layers is studied in detail.
- Published
- 2017
35. Stability at Scale: Challenges of Module Interconnects for Perovskite Photovoltaics
- Author
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Alan Sellinger, Fei Zhang, Tracy H. Schloemer, Jeffrey A. Christians, Joseph M. Luther, Matthew O. Reese, Joseph J. Berry, Rosemary C. Bramante, Maikel F.A.M. van Hest, and Kai Zhu
- Subjects
Materials science ,Scale (ratio) ,Renewable Energy, Sustainability and the Environment ,business.industry ,Energy Engineering and Power Technology ,Perovskite solar cell ,02 engineering and technology ,010402 general chemistry ,021001 nanoscience & nanotechnology ,01 natural sciences ,Stability (probability) ,Engineering physics ,0104 chemical sciences ,Fuel Technology ,Chemistry (miscellaneous) ,Photovoltaics ,Scalability ,Materials Chemistry ,0210 nano-technology ,business ,Perovskite (structure) - Abstract
Uniting efficiency, scalability, and stability is the next frontier for perovskite solar cells. Stability tests conducted on efficient perovskite solar cell mini-module architectures reveal promising stability yet also the stability challenges of scale up.
- Published
- 2018
36. Hydrazine-Free Solution-Deposited CuIn(S,Se)2 Solar Cells by Spray Deposition of Metal Chalcogenides
- Author
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John M. Walls, Andrei V. Malkov, Maikel F.A.M. van Hest, Panagiota Arnou, Carl S. Cooper, and Jake W. Bowers
- Subjects
chemistry.chemical_classification ,Materials science ,Sulfide ,Chalcopyrite ,business.industry ,Hydrazine ,Dithiol ,Nanotechnology ,02 engineering and technology ,010402 general chemistry ,021001 nanoscience & nanotechnology ,Solar energy ,01 natural sciences ,Copper indium gallium selenide solar cells ,0104 chemical sciences ,chemistry.chemical_compound ,chemistry ,Chemical engineering ,visual_art ,visual_art.visual_art_medium ,Deposition (phase transition) ,General Materials Science ,Thin film ,0210 nano-technology ,business - Abstract
Solution processing of semiconductors, such as CuInSe2 and its alloys (CIGS), can significantly reduce the manufacturing costs of thin film solar cells. Despite the recent success of solution deposition approaches for CIGS, toxic reagents such as hydrazine are usually involved, which introduce health and safety concerns. Here, we present a simple and safer methodology for the preparation of high-quality CuIn(S, Se)2 absorbers from metal sulfide solutions in a diamine/dithiol mixture. The solutions are sprayed in air, using a chromatography atomizer, followed by a postdeposition selenization step. Two different selenization methods are explored resulting in power conversion efficiencies of up to 8%.
- Published
- 2016
37. The formation mechanism for printed silver-contacts for silicon solar cells
- Author
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Jeremy Fields, Vanessa L. Pool, Jiafan Yu, Philip A. Parilla, Douglas G. Van Campen, Md. Imteyaz Ahmad, Michael F. Toney, and Maikel F.A.M. van Hest
- Subjects
Materials science ,Silicon ,Science ,General Physics and Astronomy ,chemistry.chemical_element ,Nanotechnology ,02 engineering and technology ,01 natural sciences ,General Biochemistry, Genetics and Molecular Biology ,Article ,law.invention ,law ,0103 physical sciences ,Solar cell ,Deposition (law) ,010302 applied physics ,Multidisciplinary ,integumentary system ,Precipitation (chemistry) ,business.industry ,General Chemistry ,021001 nanoscience & nanotechnology ,Solar energy ,Electrical contacts ,chemistry ,Nanocrystal ,biological sciences ,0210 nano-technology ,business ,Frit - Abstract
Screen-printing provides an economically attractive means for making Ag electrical contacts to Si solar cells, but the use of Ag substantiates a significant manufacturing cost, and the glass frit used in the paste to enable contact formation contains Pb. To achieve optimal electrical performance and to develop pastes with alternative, abundant and non-toxic materials, a better understanding the contact formation process during firing is required. Here, we use in situ X-ray diffraction during firing to reveal the reaction sequence. The findings suggest that between 500 and 650 °C PbO in the frit etches the SiNx antireflective-coating on the solar cell, exposing the Si surface. Then, above 650 °C, Ag+ dissolves into the molten glass frit – key for enabling deposition of metallic Ag on the emitter surface and precipitation of Ag nanocrystals within the glass. Ultimately, this work clarifies contact formation mechanisms and suggests approaches for development of inexpensive, nontoxic solar cell contacting pastes., The mechanism of contact formation during the firing of screen-printed contacts to Si solar cells remains elusive. Here, Fields et al. use in situ X-ray diffraction during firing to reveal the reaction sequence, thus suggesting approaches for development of inexpensive, nontoxic solar cell contacting pastes.
- Published
- 2015
38. Stable p–i–n FAPbBr 3 Devices with Improved Efficiency Using Sputtered ZnO as Electron Transport Layer
- Author
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Sumanshu Agarwal, Shaibal K. Sarkar, Pradeep R. Nair, Anand S. Subbiah, Maikel F.A.M. van Hest, and Neha Mahuli
- Subjects
Materials science ,business.industry ,Open-circuit voltage ,Mechanical Engineering ,Analytical chemistry ,02 engineering and technology ,Sputter deposition ,010402 general chemistry ,021001 nanoscience & nanotechnology ,01 natural sciences ,0104 chemical sciences ,Formamidinium ,PEDOT:PSS ,Mechanics of Materials ,Sputtering ,Optoelectronics ,0210 nano-technology ,business ,Layer (electronics) ,Short circuit ,Solution process - Abstract
Radio-frequency magnetron sputtering is demonstrated as an effective tool to deposit highly crystalline thin zinc oxide (ZnO) layer directly on perovskite absorber as an electron transport layer (ETL). As an absorber, formamidinium lead tribromide (FAPbBr3) is fabricated through a modified single-step solution process using hydrogen bromide (HBr) as an additive resulting in complete surface coverage and highly crystalline material. A planar p–i–n device architecture with spin-coated poly-(3,4-ethylenedioxythiophene):poly-styrenesulfonic acid (PEDOT:PSS) as hole transport material (HTM) and sputtered ZnO as ETL results in a short circuit current density of 9.5 mA cm−2 and an open circuit potential of 1.19 V. Numerical simulations are performed to validate the underlying loss mechanisms. The use of phenyl C60 butyric acid methyl ester (PCBM) interface layer between FAPbBr3 and sputter-coated ZnO offers shielding from potential plasma-related interface damage. The modified interface results in a better device efficiency of 8.3% with an open circuit potential of 1.35 V. Such devices offer better stability under continuous illumination under ambient conditions in comparison with the conventional organic ETL (PCBM)-based devices.
- Published
- 2017
39. Improved fill factors in solution-processed ZnO/Cu2O photovoltaics
- Author
-
Joseph J. Berry, Ajaya K. Sigdel, Maikel F.A.M. van Hest, Richard H. Friend, Andrew Marin, David S. Ginley, Judith L. MacManus-Driscoll, and Talia S. Gershon
- Subjects
Materials science ,Morphology (linguistics) ,Nucleation ,chemistry.chemical_element ,02 engineering and technology ,Zinc ,010402 general chemistry ,7. Clean energy ,01 natural sciences ,Photovoltaics ,Materials Chemistry ,business.industry ,Metals and Alloys ,Surfaces and Interfaces ,021001 nanoscience & nanotechnology ,Solar energy ,Decomposition ,0104 chemical sciences ,Surfaces, Coatings and Films ,Electronic, Optical and Magnetic Materials ,Semiconductor ,chemistry ,Chemical engineering ,0210 nano-technology ,business ,Layer (electronics) - Abstract
The influence of semiconductor layer morphology on the performance of solution-processed ZnO/Cu2O photovoltaics has been examined. ZnO films were prepared using three highly scalable, cost-effective methods: electrodeposition, zinc acetate decomposition, and diethyl zinc decomposition. To optimize device performance, it is found that a low density of nano-scale pores in the ZnO layer and large grains in the Cu2O is necessary. Through optimizing the ZnO morphology, one of the highest fill factors observed to date (up to 54%) in solution-processed ZnO/Cu2O was achieved. This value is comparable with the fill factor of the record-efficiency ZnO/Cu2O device, which was prepared with much larger energy inputs.
- Published
- 2013
- Full Text
- View/download PDF
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