Your search keyword '"Baran, Derya"' showing total 19 results

1. Rationalizing the Influence of Tunable Energy Levels on Quantum Efficiency to Design Optimal Non‐Fullerene Acceptor‐Based Ternary Organic Solar Cells.

Author

Karuthedath, Safakath, Paleti, Sri H. K., Sharma, Anirudh, Yin, Hang, P. De Castro, Catherine S., Chen, Si, Xu, Han, Alshehri, Nisreen, Ramos, Nicolas, Khan, Jafar I., Martin, Jaime, Li, Gang, Laquai, Frédéric, Baran, Derya, and Gorenflot, Julien

Subjects

SOLAR cells, QUANTUM efficiency, ELECTRON donors, IONIZATION energy, CHARGE exchange, CHARGE transfer

Abstract

Non‐fullerene acceptor (NFA)‐based ternary bulk heterojunction solar cells (TSC) are the most efficient organic solar cells (OSCs) today due to their broader absorption and quantum efficiencies (QE) often surpassing those of corresponding binary blends. The impact on QE of the energetics driving charge transfer at the electron donor:electron acceptor (D/A) interfaces is studied in blends of PBDB‐T‐2F donor with several pairs of lower bandgap NFAs. As in binary blends, the ionization energy offset between donor and acceptor (ΔIE) controls the QE and maximizes for ΔIE > 0.5 eV. However, ΔIE is not controlled by the individual NFAs IEs but by their average, weighted for their blending ratio. Using this property, the QE of a PBDB‐T‐2F:IEICO binary blend that has an insufficient ΔIE for charge generation is improved by adding a deep IE third component: IT‐4F. Combining two NFAs enables to optimize the D/A energy alignment and cells' QE without molecular engineering. [ABSTRACT FROM AUTHOR]

Published

2023

2. Device Performance of Emerging Photovoltaic Materials (Version 3).

Author

Almora, Osbel, Baran, Derya, Bazan, Guillermo C., Cabrera, Carlos I., Erten‐Ela, Sule, Forberich, Karen, Guo, Fei, Hauch, Jens, Ho‐Baillie, Anita W. Y., Jacobsson, T. Jesper, Janssen, Rene A. J., Kirchartz, Thomas, Kopidakis, Nikos, Loi, Maria A., Lunt, Richard R., Mathew, Xavier, McGehee, Michael D., Min, Jie, Mitzi, David B., and Nazeeruddin, Mohammad K.

Subjects

*PHOTOVOLTAIC power systems, *SOLAR cells, *OPEN-circuit voltage, *SHORT-circuit currents, *CELL junctions, *SCHOLARLY periodicals

Abstract

Following the 2nd release of the "Emerging PV reports," the best achievements in the performance of emerging photovoltaic devices in diverse emerging photovoltaic research subjects are summarized, as reported in peer‐reviewed articles in academic journals since August 2021. Updated graphs, tables, and analyses are provided with several performance parameters, e.g., power conversion efficiency, open‐circuit voltage, short‐circuit current density, fill factor, light utilization efficiency, and stability test energy yield. These parameters are presented as a function of the photovoltaic bandgap energy and the average visible transmittance for each technology and application, and are put into perspective using, e.g., the detailed balance efficiency limit. The 3rd installment of the "Emerging PV reports" extends the scope toward triple junction solar cells. [ABSTRACT FROM AUTHOR]

Published

2023

3. Device Performance of Emerging Photovoltaic Materials (Version 2).

Author

Almora, Osbel, Baran, Derya, Bazan, Guillermo C., Berger, Christian, Cabrera, Carlos I., Catchpole, Kylie R., Erten‐Ela, Sule, Guo, Fei, Hauch, Jens, Ho‐Baillie, Anita W. Y., Jacobsson, T. Jesper, Janssen, Rene A. J., Kirchartz, Thomas, Kopidakis, Nikos, Li, Yongfang, Loi, Maria A., Lunt, Richard R., Mathew, Xavier, McGehee, Michael D., and Min, Jie

Subjects

*SOLAR cells, *OPEN-circuit voltage, *SHORT-circuit currents, *SCHOLARLY periodicals, *ELECTRON donors

Abstract

Following the 1st release of the "Emerging photovoltaic (PV) reports", the best achievements in the performance of emerging photovoltaic devices in diverse emerging photovoltaic research subjects are summarized, as reported in peer‐reviewed articles in academic journals since August 2020. Updated graphs, tables, and analyses are provided with several performance parameters, e.g., power conversion efficiency, open‐circuit voltage, short‐circuit current density, fill factor, light utilization efficiency, and stability test energy yield. These parameters are presented as a function of the photovoltaic bandgap energy and the average visible transmittance for each technology and application and are put into perspective using, e.g., the detailed balance efficiency limit. The 2nd instalment of the "Emerging PV reports" extends the scope toward tandem solar cells and presents the current state‐of‐the‐art in tandem solar cell performance for various material combinations. [ABSTRACT FROM AUTHOR]

Published

2021

4. Chemical Design Rules for Non‐Fullerene Acceptors in Organic Solar Cells.

Author

Markina, Anastasia, Lin, Kun‐Han, Liu, Wenlan, Poelking, Carl, Firdaus, Yuliar, Villalva, Diego Rosas, Khan, Jafar I., Paleti, Sri H. K., Harrison, George T., Gorenflot, Julien, Zhang, Weimin, De Wolf, Stefaan, McCulloch, Iain, Anthopoulos, Thomas D., Baran, Derya, Laquai, Frédéric, and Andrienko, Denis

Subjects

SOLAR cells, PHOTOVOLTAIC power systems, MOLECULAR magnetic moments, MOLECULAR orientation, SOLAR cell efficiency, FULLERENES, OPEN-circuit voltage, ELECTROSTATIC fields

Abstract

Efficiencies of organic solar cells have practically doubled since the development of non‐fullerene acceptors (NFAs). However, generic chemical design rules for donor‐NFA combinations are still needed. Such rules are proposed by analyzing inhomogeneous electrostatic fields at the donor–acceptor interface. It is shown that an acceptor–donor–acceptor molecular architecture, and molecular alignment parallel to the interface, results in energy level bending that destabilizes the charge transfer state, thus promoting its dissociation into free charges. By analyzing a series of PCE10:NFA solar cells, with NFAs including Y6, IEICO, and ITIC, as well as their halogenated derivatives, it is suggested that the molecular quadrupole moment of ≈75 Debye Å balances the losses in the open circuit voltage and gains in charge generation efficiency. [ABSTRACT FROM AUTHOR]

Published

2021

5. Linked Nickel Oxide/Perovskite Interface Passivation for High‐Performance Textured Monolithic Tandem Solar Cells.

Author

Zhumagali, Shynggys, Isikgor, Furkan H., Maity, Partha, Yin, Jun, Ugur, Esma, De Bastiani, Michele, Subbiah, Anand S., Mirabelli, Alessandro James, Azmi, Randi, Harrison, George T., Troughton, Joel, Aydin, Erkan, Liu, Jiang, Allen, Thomas, Rehman, Atteq ur, Baran, Derya, Mohammed, Omar F., and De Wolf, Stefaan

Subjects

PHOTOVOLTAIC power systems, NICKEL oxide, SOLAR cells, PEROVSKITE, SILICON solar cells, PASSIVATION, NICKEL oxides, OPTOELECTRONIC devices

Abstract

Sputtered nickel oxide (NiOx) is an attractive hole‐transport layer for efficient, stable, and large‐area p‐i‐n metal‐halide perovskite solar cells (PSCs). However, surface traps and undesirable chemical reactions at the NiOx/perovskite interface are limiting the performance of NiOx‐based PSCs. To address these issues simultaneously, an efficient NiOx/perovskite interface passivation strategy by using an organometallic dye molecule (N719) is reported. This molecule concurrently passivates NiOx and perovskite surface traps, and facilitates charge transport. Consequently, the power conversion efficiency (PCE) of single‐junction p‐i‐n PSCs increases from 17.3% to 20.4% (the highest reported value for sputtered‐NiOx based PSCs). Notably, the N719 molecule self‐anchors and conformally covers NiOx films deposited on complex surfaces. This enables highly efficient textured monolithic p‐i‐n perovskite/silicon tandem solar cells, reaching PCEs up to 26.2% (23.5% without dye passivation) with a high processing yield. The N719 layer also forms a barrier that prevents undesirable chemical reactions at the NiOx/perovskite interface, significantly improving device stability. These findings provide critical insights for improved passivation of the NiOx/perovskite interface, and the fabrication of highly efficient, robust, and large‐area perovskite‐based optoelectronic devices. [ABSTRACT FROM AUTHOR]

Published

2021

6. Efficient Hybrid Amorphous Silicon/Organic Tandem Solar Cells Enabled by Near‐Infrared Absorbing Nonfullerene Acceptors.

Author

Troughton, Joel, Neubert, Sebastian, Gasparini, Nicola, Villalva, Diego Rosas, Bertrandie, Jules, Seitkhan, Akmaral, Paleti, Sri Harish Kumar, Sharma, Anirudh, De Bastiani, Michele, Aydin, Erkan, Anthopoulos, Thomas D., De Wolf, Stefaan, Schlatmann, Rutger, and Baran, Derya

Subjects

AMORPHOUS silicon, PHOTOVOLTAIC power systems, SOLAR cells, SOLAR radiation, LIGHT intensity, ORGANIC bases

Abstract

Monolithically stacked tandem solar cells present opportunities to absorb more of the sun's radiation while reducing the degree of energetic loss through thermalization. In these applications, the bandgap of the tandem's constituent subcells must be carefully adjusted so as to avoid competition for photons. Organic photovoltaics based on nonfullerene acceptors (NFAs) have recently exploded in popularity owing to the ease with which their electrical and optical properties can be tuned through chemistry. Here, highly complementary and efficient 2‐terminal tandem solar cells are reported based on a wide bandgap amorphous silicon absorber, and a narrow bandgap NFA bulk‐heterojunction with power conversion efficiencies (PCEs) exceeding 15%. Interface engineering of this tandem device allows for high PCEs across a wide range of light intensities both above and below "1 sun." Furthermore, the addition of an inorganic silicon subcell enhances the operational stability of the tandem by reducing the light‐stress experienced by the bulk heterojunction, resolving a long‐standing stumbling block in organic photovoltaic research. [ABSTRACT FROM AUTHOR]

Published

2021

7. Device Performance of Emerging Photovoltaic Materials (Version 1).

Author

Almora, Osbel, Baran, Derya, Bazan, Guillermo C., Berger, Christian, Cabrera, Carlos I., Catchpole, Kylie R., Erten‐Ela, Sule, Guo, Fei, Hauch, Jens, Ho‐Baillie, Anita W. Y., Jacobsson, T. Jesper, Janssen, Rene A. J., Kirchartz, Thomas, Kopidakis, Nikos, Li, Yongfang, Loi, Maria A., Lunt, Richard R., Mathew, Xavier, McGehee, Michael D., and Min, Jie

Subjects

*BUILDING-integrated photovoltaic systems, *ELECTRIC power production, *SOLAR cells, *PHOTOVOLTAIC power generation

Abstract

Emerging photovoltaics (PVs) focus on a variety of applications complementing large scale electricity generation. Organic, dye‐sensitized, and some perovskite solar cells are considered in building integration, greenhouses, wearable, and indoor applications, thereby motivating research on flexible, transparent, semitransparent, and multi‐junction PVs. Nevertheless, it can be very time consuming to find or develop an up‐to‐date overview of the state‐of‐the‐art performance for these systems and applications. Two important resources for recording research cells efficiencies are the National Renewable Energy Laboratory chart and the efficiency tables compiled biannually by Martin Green and colleagues. Both publications provide an effective coverage over the established technologies, bridging research and industry. An alternative approach is proposed here summarizing the best reports in the diverse research subjects for emerging PVs. Best performance parameters are provided as a function of the photovoltaic bandgap energy for each technology and application, and are put into perspective using, e.g., the Shockley–Queisser limit. In all cases, the reported data correspond to published and/or properly described certified results, with enough details provided for prospective data reproduction. Additionally, the stability test energy yield is included as an analysis parameter among state‐of‐the‐art emerging PVs. [ABSTRACT FROM AUTHOR]

Published

2021

8. Processing‐Performance Evolution of Perovskite Solar Cells: From Large Grain Polycrystalline Films to Single Crystals.

Author

Haque, Md Azimul, Troughton, Joel, and Baran, Derya

Subjects

SOLAR cells, SINGLE crystals, PEROVSKITE, POLYMER films, GRAIN, CRYSTAL grain boundaries

Abstract

Solution‐processable halide perovskites have emerged as strong contenders for next‐generation solar cells owing to their favorable optoelectronic properties. To maintain the efficiency momentum of perovskite solar cells (PSCs), development of advanced processing techniques, particularly for the perovskite layer, is imperative. There is a close correlation between the quality of the perovskite layer and its photophysical properties: Highly crystalline large grains with uniform morphology of the perovskite layer and their interface with charge transporters are crucial for achieving high performance. Significant efforts have been dedicated to achieve perovskite films with large grains reaching the millimeter‐scale for high‐efficiency PSCs. Recent work showcases a transition from large grain polycrystalline to single‐crystalline (SC) PSCs made possible by the facile growth of perovskite single crystals. In this review, the recent progress of the large grain polycrystalline PSCs and grain boundary‐free SC‐PSCs is reported, particularly focusing on the recent approach of depositing large‐grained perovskite layers and single crystal growth technique, that have been adopted for fabrication of efficient PSCs. In addition, prospects of SC‐PSCs and their further development in terms of efficiency, device design, scalability, and stability are discussed. [ABSTRACT FROM AUTHOR]

Published

2020

9. Progress in Poly (3‐Hexylthiophene) Organic Solar Cells and the Influence of Its Molecular Weight on Device Performance.

Author

Wadsworth, Andrew, Hamid, Zeinab, Bidwell, Matthew, Ashraf, Raja S., Khan, Jafar I., Anjum, Dalaver H., Cendra, Camila, Yan, Jun, Rezasoltani, Elham, Guilbert, Anne A. Y., Azzouzi, Mohammed, Gasparini, Nicola, Bannock, James H., Baran, Derya, Wu, Hongbin, de Mello, John C., Brabec, Christoph J., Salleo, Alberto, Nelson, Jenny, and Laquai, Frédéric

Subjects

SOLAR cells, MOLECULAR weights, POLYMERS, PHOTOVOLTAIC cells, ELECTROPHILES

Abstract

Abstract: Poly (3‐hexylthiophene) (P3HT) was an early frontrunner in the development of donor polymers to be used in organic photovoltaics. A relatively straightforward and inexpensive synthesis suggests that it may be the most viable donor polymer to use in large‐scale commercial organic solar cells. Replacing fullerenes with new electron acceptors has led to significant improvements in device performance and stability, with devices now able to exceed an efficiency of 7%. Past studies have reported a dependence of device performance on the molecular weight of the polymer in fullerene‐containing blends, however, with nonfullerene acceptors now showing promise a similar study was needed. P3HT blends, with two nonfullerene acceptors (O‐IDTBR and EH‐IDTBR), were probed using a number of polymer batches with varying molecular weights. O‐IDTBR was shown to exhibit a dependence on the polymer molecular weight, with optimal performance achieved with a 34 kDa polymer, while EH‐IDTBR displayed an independence in performance with varying polymer molecular weight. Probing the thermal and morphological behavior of the P3HT:O‐IDTBR blends suggests that an optimal morphology with pronounced donor and acceptor domains was only achieved with the 34 kDa polymer, and a greater degree of mixing was exhibited in the other blends, likely leading to poorer device performance. [ABSTRACT FROM AUTHOR]

Published

2018

10. The Physics of Small Molecule Acceptors for Efficient and Stable Bulk Heterojunction Solar Cells.

Author

Gasparini, Nicola, Wadsworth, Andrew, Moser, Maximilian, Baran, Derya, McCulloch, Iain, and Brabec, Christoph J.

Subjects

SOLAR cells, HETEROJUNCTIONS, ENERGY conversion, CHARGE transfer, FULLERENES

Abstract

Abstract: Organic bulk heterojunction solar cells based on small molecule acceptors have recently seen a rapid rise in the power conversion efficiency with values exceeding 13%. This impressive achievement has been obtained by simultaneous reduction of voltage and charge recombination losses within this class of materials as compared to fullerene‐based solar cells. In this contribution, the authors review the current understanding of the relevant photophysical processes in highly efficient nonfullerene acceptor (NFA) small molecules. Charge generation, recombination, and charge transport is discussed in comparison to fullerene‐based composites. Finally, the authors review the superior light and thermal stability of nonfullerene small molecule acceptor based solar cells, and highlight the importance of NFA‐based composites that enable devices without early performance loss, thus resembling so‐called burn‐in free devices. [ABSTRACT FROM AUTHOR]

Published

2018

11. Polymer:Nonfullerene Bulk Heterojunction Solar Cells with Exceptionally Low Recombination Rates.

Author

Gasparini, Nicola, Salvador, Michael, Heumueller, Thomas, Richter, Moses, Classen, Andrej, Shrestha, Shreetu, Matt, Gebhard J., Holliday, Sarah, Strohm, Sebastian, Egelhaaf, Hans‐Joachim, Wadsworth, Andrew, Baran, Derya, McCulloch, Iain, and Brabec, Christoph J.

Subjects

POLYMERS, SOLAR cells, HETEROJUNCTIONS, ORGANIC semiconductors, CHARGE carrier mobility, POLY(3-hexylthiophene), ENERGY conversion, LANGEVIN equations

Abstract

Organic semiconductors are in general known to have an inherently lower charge carrier mobility compared to their inorganic counterparts. Bimolecular recombination of holes and electrons is an important loss mechanism and can often be described by the Langevin recombination model. Here, the device physics of bulk heterojunction solar cells based on a nonfullerene acceptor (IDTBR) in combination with poly(3-hexylthiophene) (P3HT) are elucidated, showing an unprecedentedly low bimolecular recombination rate. The high fill factor observed (above 65%) is attributed to non-Langevin behavior with a Langevin prefactor (β/βL) of 1.9 × 10−4. The absence of parasitic recombination and high charge carrier lifetimes in P3HT:IDTBR solar cells inform an almost ideal bimolecular recombination behavior. This exceptional recombination behavior is explored to fabricate devices with layer thicknesses up to 450 nm without significant performance losses. The determination of the photoexcited carrier mobility by time-of-flight measurements reveals a long-lived and nonthermalized carrier transport as the origin for the exceptional transport physics. The crystalline microstructure arrangement of both components is suggested to be decisive for this slow recombination dynamics. Further, the thickness-independent power conversion efficiency is of utmost technological relevance for upscaling production and reiterates the importance of understanding material design in the context of low bimolecular recombination. [ABSTRACT FROM AUTHOR]

Published

2017

12. Nanoscale Morphology of Doctor Bladed versus Spin-Coated Organic Photovoltaic Films.

Author

Pokuri, Balaji Sesha Sarath, Sit, Joseph, Wodo, Olga, Baran, Derya, Ameri, Tayebeh, Brabec, Christoph J., Moule, Adam J., and Ganapathysubramanian, Baskar

Subjects

MORPHOLOGY, PHOTOVOLTAIC power generation, EXCITON theory, DISSOCIATION (Chemistry), PROCESS optimization

Abstract

Recent advances in efficiency of organic photovoltaics are driven by judicious selection of processing conditions that result in a 'desired' morphology. An important theme of morphology research is quantifying the effect of processing conditions on morphology and relating it to device efficiency. State-of-the-art morphology quantification methods provide film-averaged or 2D-projected features that only indirectly correlate with performance, making causal reasoning nontrivial. Accessing the 3D distribution of material, however, provides a means of directly mapping processing to performance. In this paper, two recently developed techniques are integrated-reconstruction of 3D morphology and subsequent conversion into intuitive morphology descriptors -to comprehensively image and quantify morphology. These techniques are applied on films generated by doctor blading and spin coating, additionally investigating the effect of thermal annealing. It is found that morphology of all samples exhibits very high connectivity to electrodes. Not surprisingly, thermal annealing consistently increases the average domain size in the samples, aiding exciton generation. Furthermore, annealing also improves the balance of interfaces, enhancing exciton dissociation. A comparison of morphology descriptors impacting each stage of photophysics (exciton generation, dissociation, and charge transport) reveals that spin-annealed sample exhibits superior morphology-based performance indicators. This suggests substantial room for improvement of blade-based methods (process optimization) for morphology tuning to enhance performance of large area devices. [ABSTRACT FROM AUTHOR]

Published

2017

13. Burn-in Free Nonfullerene-Based Organic Solar Cells.

Author

Gasparini, Nicola, Salvador, Michael, Strohm, Sebastian, Heumueller, Thomas, Levchuk, Ievgen, Wadsworth, Andrew, Bannock, James H., de Mello, John C., Egelhaaf, Hans‐Joachim, Baran, Derya, McCulloch, Iain, and Brabec, Christoph J.

Subjects

SOLAR cells, FULLERENES, THIOPHENES, MOLECULAR weights, BUTYRIC acid, DIMERIZATION

Abstract

Organic solar cells that are free of burn-in, the commonly observed rapid performance loss under light, are presented. The solar cells are based on poly(3-hexylthiophene) (P3HT) with varying molecular weights and a nonfullerene acceptor (rhodanine-benzothiadiazole-coupled indacenodithiophene, IDTBR) and are fabricated in air. P3HT:IDTBR solar cells light-soaked over the course of 2000 h lose about 5% of power conversion efficiency (PCE), in stark contrast to [6,6]-Phenyl C61 butyric acid methyl ester (PCBM)-based solar cells whose PCE shows a burn-in that extends over several hundreds of hours and levels off at a loss of ≈34%. Replacing PCBM with IDTBR prevents short-circuit current losses due to fullerene dimerization and inhibits disorder-induced open-circuit voltage losses, indicating a very robust device operation that is insensitive to defect states. Small losses in fill factor over time are proposed to originate from polymer or interface defects. Finally, the combination of enhanced efficiency and stability in P3HT:IDTBR increases the lifetime energy yield by more than a factor of 10 when compared with the same type of devices using a fullerene-based acceptor instead. [ABSTRACT FROM AUTHOR]

Published

2017

14. Environmentally Printing Efficient Organic Tandem Solar Cells with High Fill Factors: A Guideline Towards 20% Power Conversion Efficiency.

Author

Li, Ning, Baran, Derya, Spyropoulos, George D., Zhang, Hong, Berny, Stephane, Turbiez, Mathieu, Ameri, Tayebeh, Krebs, Frederik C., and Brabec, Christoph J.

Subjects

*SOLAR cells, *ENERGY harvesting, *PHOTOVOLTAIC cells, *DIRECT energy conversion, *BAND gaps

Abstract

The tandem concept involves stacking two or more cells with complementary absorption spectra in series or parallel connection, harvesting photons at the highest possible potential. It is strongly suggested that the roll-to-roll production of organic solar cells will employ the tandem concept to enhance the power conversion efficiency (PCE). However, due to the undeveloped deposition techniques, the challenges in ink formulation as well as the lack of commercially available high performance active materials, roll-to-roll fabrication of highly efficient organic tandem solar cells currently presents a major challenge. The reported high PCE values from lab-scale spin-coated devices are, of course, representative, but not helpful for commercialization. Here, organic tandem solar cells with exceptionally high fill factors and PCE values of 7.66% (on glass) and 5.56% (on flexible substrate), which are the highest values for the solution-processed tandem solar cells fabricated by a mass-production compatible coating technique under ambient conditions, are demonstrated. To predict the highest possible performance of tandem solar cells, optical simulation based on experimentally feasible values is performed. A maximum PCE of 21% is theoretically achievable for an organic tandem solar cell based on the optimized bandgaps and achieved fill factors. [ABSTRACT FROM AUTHOR]

Published

2014

15. An Efficient Solution-Processed Intermediate Layer for Facilitating Fabrication of Organic Multi-Junction Solar Cells.

Author

Li, Ning, Baran, Derya, Forberich, Karen, Turbiez, Mathieu, Ameri, Tayebeh, Krebs, Frederik C., and Brabec, Christoph J.

Subjects

*SOLAR energy, *PHOTOVOLTAIC cells, *RENEWABLE energy sources, *ENERGY conservation, *ENERGY management

Abstract

Photovoltaic tandem technology has the potential to boost the power conversion efficiency of organic photovoltaic devices. Here, a reliable and efficient fully solution-processed intermediate layer (IML) consisting of ZnO and neutralized poly(3,4-ethylenedioxythiophene):poly(styrenesulfonate) (PEDOT:PSS) is demonstrated for series-connected multi-junction organic solar cells (OSCs). Drying at 80 °C in air is sufficient for this solution-processed IML to obtain excellent functionality and reliability, which allow the use of most of high performance donor materials in the tandem structure. An open circuit voltage ( Voc) of 0.56 V is obtained for single-junction OSCs based on a low band-gap polymer, while multi-junction OSCs based on the same absorber material deliver promising fill factor values along with fully additive Voc as the number of junctions increase. Optical and electrical simulations, which are reliable and promising guidelines for the design and investigation of multi-junction OSCs, are discussed. The outcome of optical and electrical simulations is in excellent agreement with the experimental data, indicating the outstanding efficiency and functionality of this solution-processed IML. The demonstration of this efficient, solution-processed IML represents a convenient way for facilitating fabrication of multi-junction OSCs to achieve high power conversion efficiency. [ABSTRACT FROM AUTHOR]

Published

2013

16. Design of the Solution-Processed Intermediate Layer by Engineering for Inverted Organic Multi junction Solar Cells.

Author

Li, Ning, Stubhan, Tobias, Baran, Derya, Min, Jie, Wang, Haiqiao, Ameri, Tayebeh, and Brabec, Christoph J.

Abstract

An equivalent ohmic contact is successfully formed between low‐conductivity poly(3,4‐ethylenedioxythiophene):poly(styrenesulfonate)(PEDOT:PSS) and solution‐processed aluminum‐doped ZnO (AZO). Because of its promising optical and electrical properties, this combination can serve as an efficient interconnection layer as well as an optical spacer in inverted‐structure organic tandem devices. [ABSTRACT FROM AUTHOR]

Published

2013

17. Performance Enhancement of the P3HT/PCBM Solar Cells through NIR Sensitization Using a Small-Bandgap Polymer.

Author

Ameri, Tayebeh, Min, Jie, Li, Ning, Machui, Florian, Baran, Derya, Forster, Michael, Schottler, Kristina J., Dolfen, Daniel, Scherf, Ullrich, and Brabec, Christoph J.

Published

2012

18. Highly Passivated n‐Type Colloidal Quantum Dots for Solution‐Processed Thermoelectric Generators with Large Output Voltage.

Author

Nugraha, Mohamad I., Kim, Hyunho, Sun, Bin, Desai, Saheena, de Arquer, F. Pelayo Garcia, Sargent, Edward H., Alshareef, Husam N., and Baran, Derya

Subjects

SEMICONDUCTOR nanocrystals, THERMOELECTRIC generators, QUANTUM dots, N-type semiconductors, SURFACE passivation, THERMOELECTRIC materials, THERMOELECTRIC power

Abstract

Colloidal quantum dots (CQDs) are attractive materials for thermoelectric applications due to their simple and low‐cost processing; advantageously, they also offer low thermal conductivity and high Seebeck coefficient. To date, the majority of CQD thermoelectric films reported upon have been p‐type, while only a few reports are available on n‐type films. High‐performing n‐ and p‐type films are essential for thermoelectric generators (TEGs) with large output voltage and power. Here, high‐thermoelectric‐performance n‐type CQD films are reported and showcased in high‐performance all‐CQD TEGs. By engineering the electronic coupling in the films, a thorough removal of insulating ligands is achieved and this is combined with excellent surface trap passivation. This enables a high thermoelectric power factor of 24 µW m−1 K−2, superior to previously reported n‐type lead chalcogenide CQD films operating near room temperature (<1 µW m−1 K−2). As a result, an all‐CQD film TEG with a large output voltage of 0.25 V and a power density of 0.63 W m−2 at ∆T = 50 K is demonstrated, which represents an over fourfold enhancement to previously reported p‐type only CQD TEGs. [ABSTRACT FROM AUTHOR]

Published

2019

19. Low‐Temperature‐Processed Colloidal Quantum Dots as Building Blocks for Thermoelectrics.

Author

Nugraha, Mohamad I., Kim, Hyunho, Sun, Bin, Haque, Md Azimul, Arquer, Francisco Pelayo Garcia, Villalva, Diego Rosas, El‐Labban, Abdulrahman, Sargent, Edward H., Alshareef, Husam N., and Baran, Derya

Subjects

SEMICONDUCTOR nanocrystals, QUANTUM dots, SEEBECK coefficient, THERMOELECTRIC generators, CARRIER density, THERMAL conductivity

Abstract

Colloidal quantum dots (CQDs) are demonstrated to be promising materials to realize high‐performance thermoelectrics owing to their low thermal conductivity. The most studied CQD films, however, are using long ligands that require high processing and operation temperature (>400 °C) to achieve optimum thermoelectric performance. Here the thermoelectric properties of CQD films cross‐linked using short ligands that allow strong inter‐QD coupling are reported. Using the ligands, p‐type thermoelectric solids are demonstrated with a high Seebeck coefficient and power factor of 400 μV K−1 and 30 µW m−1 K−2, respectively, leading to maximum ZT of 0.02 at a lower measurement temperature (<400 K) and lower processing temperature (<300 °C). These ligands further reduce the annealing temperature to 175 °C, significantly increasing the Seebeck coefficient of the CQD films to 580 μV K−1. This high Seebeck coefficient with a superior ZT near room temperature compared to previously reported high temperature‐annealed CQD films is ascribed to the smaller grain size, which enables the retainment of quantum confinement and significantly increases the hole effective mass in the films. This study provides a pathway to approach quantum confinement for achieving a high Seebeck coefficient yet strong inter‐QD coupling, which offers a step toward low‐temperature‐processed high‐performance thermoelectric generators. A strategy to enhance electronic coupling using short ligands that allow lower processing temperature and improved thermoelectric performance in p‐type colloidal quantum dots films is studied. The lower processing temperature is found to increase the Seebeck coefficient and reduce the in‐plane thermal conductivity of the films. Fundamental analysis on grain size, carrier density, and effective mass is highlighted to understand these findings. [ABSTRACT FROM AUTHOR]

Published

2019