Your search keyword '"Ade, Harald"' showing total 16 results

1. Regio‐Regular Polymer Acceptors Enabled by Determined Fluorination on End Groups for All‐Polymer Solar Cells with 15.2 % Efficiency.

Author

Yu, Han, Pan, Mingao, Sun, Rui, Agunawela, Indunil, Zhang, Jianquan, Li, Yuhao, Qi, Zhenyu, Han, Han, Zou, Xinhui, Zhou, Wentao, Chen, Shangshang, Lai, Joshua Yuk Lin, Luo, Siwei, Luo, Zhenghui, Zhao, Dahui, Lu, Xinhui, Ade, Harald, Huang, Fei, Min, Jie, and Yan, He

Subjects

SOLAR cells, SILICON solar cells, FLUORINATION, PHOTOVOLTAIC cells, POLYMERS, SMALL molecules, POLYMER blends

Abstract

Polymerization sites of small molecule acceptors (SMAs) play vital roles in determining device performance of all‐polymer solar cells (all‐PSCs). Different from our recent work about fluoro‐ and bromo‐ co‐modified end group of IC‐FBr (a mixture of IC‐FBr1 and IC‐FBr2), in this paper, we synthesized and purified two regiospecific fluoro‐ and bromo‐ substituted end groups (IC‐FBr‐o & IC‐FBr‐m), which were then employed to construct two regio‐regular polymer acceptors named PYF‐T‐o and PYF‐T‐m, respectively. In comparison with its isomeric counterparts named PYF‐T‐m with different conjugated coupling sites, PYF‐T‐o exhibits stronger and bathochromic absorption to achieve better photon harvesting. Meanwhile, PYF‐T‐o adopts more ordered inter‐chain packing and suitable phase separation after blending with the donor polymer PM6, which resulted in suppressed charge recombination and efficient charge transport. Strikingly, we observed a dramatic performance difference between the two isomeric polymer acceptors PYF‐T‐o and PYF‐T‐m. While devices based on PM6:PYF‐T‐o can yield power conversion efficiency (PCE) of 15.2 %, devices based on PM6:PYF‐T‐m only show poor efficiencies of 1.4 %. This work demonstrates the success of configuration‐unique fluorinated end groups in designing high‐performance regular polymer acceptors, which provides guidelines towards developing all‐PSCs with better efficiencies. [ABSTRACT FROM AUTHOR]

Published

2021

2. Effect of Palladium‐Tetrakis(Triphenylphosphine) Catalyst Traces on Charge Recombination and Extraction in Non‐Fullerene‐based Organic Solar Cells.

Author

Schopp, Nora, Brus, Viktor V., Lee, Jaewon, Dixon, Alana, Karki, Akchheta, Liu, Tuo, Peng, Zhengxing, Graham, Kenneth R., Ade, Harald, Bazan, Guillermo C., and Nguyen, Thuc‐Quyen

Subjects

SOLAR cells, SILICON solar cells, FULLERENE polymers, TRIPHENYLPHOSPHINE, SURFACE recombination, CATALYSTS, CHARGE carriers, THIOPHENES

Abstract

The effect of the cross‐coupling catalyst tetrakis(triphenylphosphine)palladium(0) (Pd(PPh3)4) on the performance of a model organic bulk‐heterojunction solar cell composed of a blend of poly([2,6′‐4,8‐di(5‐ethylhexylthienyl)benzo[1,2‐b;3,3‐b]dithiophene]{3‐fluoro‐2[(2‐ethylhexyl)carbonyl]thieno[3,4‐b]thiophenediyl}) (PTB7‐Th) donor and 3,9‐bis(2‐methylene‐((3‐(1,1‐dicyanomethylene)‐6,7‐difluoro)‐indanone))‐5,5,11,11‐tetrakis(4‐hexylphenyl)‐dithieno[2,3‐d:2′,3′‐d′]‐s‐indaceno[1,2‐b:5,6‐b′]dithiophene (IOTIC‐4F) non‐fullerene acceptor is investigated. The effect of intentional addition of different amounts of Pd(PPh3)4 on morphology, free charge carrier generation, non‐geminate bulk trap‐ and surface trap‐assisted recombination as well as bimolecular recombination and charge extraction is quantified. This work shows that free charge carrier generation is affected significantly, while the impact of Pd(PPh3)4 on non‐geminate recombination processes is limited because the catalyst does not facilitate efficient trap‐assisted recombination. The studied system shows substantial robustness towards the addition of Pd(PPh3)4 in small amounts. [ABSTRACT FROM AUTHOR]

Published

2021

3. Optimized Active Layer Morphologies via Ternary Copolymerization of Polymer Donors for 17.6 % Efficiency Organic Solar Cells with Enhanced Fill Factor.

Author

Guo, Xia, Fan, Qunping, Wu, Jingnan, Li, Guangwei, Peng, Zhongxiang, Su, Wenyan, Lin, Ji, Hou, Lintao, Qin, Yunpeng, Ade, Harald, Ye, Long, Zhang, Maojie, and Li, Yongfang

Subjects

SOLAR cell efficiency, SILICON solar cells, COPOLYMERIZATION, MOLECULAR orientation, SOLAR cells, FULLERENE polymers, MOLECULAR structure

Abstract

Regulating molecular structure to optimize the active layer morphology is of considerable significance for improving the power conversion efficiencies (PCEs) in organic solar cells (OSCs). Herein, we demonstrated a simple ternary copolymerization approach to develop a terpolymer donor PM6‐Tz20 by incorporating the 5,5′‐dithienyl‐2,2′‐bithiazole (DTBTz, 20 mol%) unit into the backbone of PM6 (PM6‐Tz00). This method can effectively tailor the molecular orientation and aggregation of the polymer, and then optimize the active layer morphology and the corresponding physical processes of devices, ultimately boosting FF and then PCE. Hence, the PM6‐Tz20: Y6‐based OSCs achieved a PCE of up to 17.1% with a significantly enhanced FF of 0.77. Using Ag (220 nm) instead of Al (100 nm) as cathode, the champion PCE was further improved to 17.6%. This work provides a simple and effective molecular design strategy to optimize the active layer morphology of OSCs for improving photovoltaic performance. [ABSTRACT FROM AUTHOR]

Published

2021

4. Asymmetric Alkoxy and Alkyl Substitution on Nonfullerene Acceptors Enabling High‐Performance Organic Solar Cells.

Author

Chen, Yuzhong, Bai, Fujin, Peng, Zhengxing, Zhu, Lei, Zhang, Jianquan, Zou, Xinhui, Qin, Yunpeng, Kim, Ha Kyung, Yuan, Jun, Ma, Lik‐Kuen, Zhang, Jie, Yu, Han, Chow, Philip C. Y., Huang, Fei, Zou, Yingping, Ade, Harald, Liu, Feng, and Yan, He

Subjects

SOLAR cells, OPEN-circuit voltage, SILICON solar cells, PHOTOVOLTAIC cells, PERYLENE, ALKOXY group, MECHANICAL properties of condensed matter, SOLUBILITY

Abstract

In this paper, a strategy of asymmetric alkyl and alkoxy substitution is applied to state‐of‐the‐art Y‐series nonfullerene acceptors (NFAs), and it achieves great performance in organic solar cell (OSC) devices. Since alkoxy groups can have a significant influence on the material properties of NFAs, alkoxy substitution is applied to the Y6 molecule in a symmetric manner. The resulting molecule (named Y6‐2O), despite showing improved open‐circuit voltage (Voc), yields extremely poor performance due to low solubility and excessive aggregation properties, a change that is due to the conformational locking effect of alkoxy groups. In contrast, asymmetric alkyl and alkoxy substitution on Y6, yields a molecule named Y6‐1O that can maintain the positive effect of Voc improvement and obtain reasonably good solubility. The resulting molecule Y6‐1O enables highly efficient nonfullerene OSCs with 17.6% efficiency and the asymmetric side‐chain strategy has the potential to be applied to other NFA‐material systems to further improve their performance. [ABSTRACT FROM AUTHOR]

Published

2021

5. Pseudo-bilayer architecture enables high-performance organic solar cells with enhanced exciton diffusion length.

Author

Jiang, Kui, Zhang, Jie, Peng, Zhengxing, Lin, Francis, Wu, Shengfan, Li, Zhen, Chen, Yuzhong, Yan, He, Ade, Harald, Zhu, Zonglong, and Jen, Alex K.-Y.

Subjects

SOLAR cells, DIFFUSION, KIRKENDALL effect, SILICON solar cells, SHORT-circuit currents, TERNARY system

Abstract

Solution-processed organic solar cells (OSCs) are a promising candidate for next-generation photovoltaic technologies. However, the short exciton diffusion length of the bulk heterojunction active layer in OSCs strongly hampers the full potential to be realized in these bulk heterojunction OSCs. Herein, we report high-performance OSCs with a pseudo-bilayer architecture, which possesses longer exciton diffusion length benefited from higher film crystallinity. This feature ensures the synergistic advantages of efficient exciton dissociation and charge transport in OSCs with pseudo-bilayer architecture, enabling a higher power conversion efficiency (17.42%) to be achieved compared to those with bulk heterojunction architecture (16.44%) due to higher short-circuit current density and fill factor. A certified efficiency of 16.31% is also achieved for the ternary OSC with a pseudo-bilayer active layer. Our results demonstrate the excellent potential for pseudo-bilayer architecture to be used for future OSC applications. The so-called pseudo-bilayer (PB) organic solar cell (OSC) device architecture can promote enhanced exciton dissociation and charge transport, leading to improved device performance. Here, the authors report high-efficiency OSCs that features a PB architecture and optimized ternary system. [ABSTRACT FROM AUTHOR]

Published

2021

6. Low Temperature Aggregation Transitions in N3 and Y6 Acceptors Enable Double‐Annealing Method That Yields Hierarchical Morphology and Superior Efficiency in Nonfullerene Organic Solar Cells.

Author

Qin, Yunpeng, Xu, Ye, Peng, Zhengxing, Hou, Jianhui, and Ade, Harald

Subjects

SOLAR cells, TRANSITION temperature, LOW temperatures, SILICON solar cells, MANUFACTURING processes, X-ray scattering, PHOTOVOLTAIC cells

Abstract

Thermal transition of organic solar cells (OSCs) constituent materials are often insufficiently researched, resulting in trial‐and‐error rather than rational approaches to annealing strategies to improve domain purity to enhance the power conversion efficiency. Despite the potential utility, little is known about the thermal transitions of the modern high‐performance acceptors Y6 and N3. Here, by using an optical method, it is discovered that the acceptor N3 has a clear solid‐state aggregation transition at 82 °C. This unusually low transition not only explains prior optimization protocols, but the transition informs and enables a double‐annealing method that can fine‐tune aggregation and the device morphology. Compared with 16.6% efficiency for PM6:N3:PC71BM control devices, higher efficiency of 17.6% is obtained through the improved protocol. Morphology characterization with x‐ray scattering methods reveals the formation of a multilength scale morphology. Moreover, the double‐annealing method is illustrated and easily transferred and validated with Y6‐based devices, using the transition of Y6 at 102 °C. As a result, the PCE improved from 16.0% to 16.8%. Design of high‐performance acceptors with yet lower aggregation transitions might be required for OSCs to successfully transition to low thermal budget industrial processing methods where annealing temperatures on plastic substrates have to be kept low. [ABSTRACT FROM AUTHOR]

Published

2020

7. Modulating Energy Level on an A‐D‐A′‐D‐A‐Type Unfused Acceptor by a Benzothiadiazole Core Enables Organic Solar Cells with Simple Procedure and High Performance.

Author

Yu, Han, Qi, Zhenyu, Li, Xingye, Wang, Zhen, Zhou, Wentao, Ade, Harald, Yan, He, and Chen, Kai

Subjects

SOLAR cells, SILICON solar cells, DYE-sensitized solar cells, SHORT-circuit currents, ABSORPTION spectra, CHARGE transfer, CHEMICAL structure

Abstract

Unfused‐ring acceptors (UFAs) have gained considerable research attention as they offer simple chemical structures through simplified synthesis methods, which would boost the commercialization of organic solar cells (OSCs). Recently, a new small molecule acceptor (SMA) named Y6 was reported, yielding high‐performance OSCs. Herein, the Y6‐like A‐DA′D‐A framework is developed to A‐D‐A′‐D‐A‐type backbone adopted in constructing UFAs. Two new Y6‐like UFAs are synthesized within four steps and the effect of noncovalent atoms at the central electron‐deficient core on material properties and device performances is studied. It is found that the introduction of fluorine atoms can bring larger red‐shift in the absorption spectra and better aggregation of the resulting UFA film states compared with those of oxygen atoms. Interestingly, the variations in the noncovalent interaction atoms induce different intermolecular charge transfer between donors and UFAs. When blended with another economical donor, PTQ10, F substitution at the benzothiadiazole ring is more effective than O substitution, leading to the increased short‐circuit current density (JSC) and higher efficiency of over 12%, among the best performances of UFA‐based OSCs. This contribution demonstrates the appropriate introduction of noncovalent interaction is a promising method for tuning energy levels, absorption, and aggregation of UFAs for high‐performance OSCs. [ABSTRACT FROM AUTHOR]

Published

2020

8. Precise Control of Phase Separation Enables 12% Efficiency in All Small Molecule Solar Cells.

Author

Bin, Haijun, Angunawela, Indunil, Qiu, Beibei, Colberts, Fallon J. M., Li, Mengmeng, Dyson, Matthew J., Wienk, Martijn M., Ade, Harald, Li, Yongfang, and Janssen, René A. J.

Subjects

SOLAR cells, PHASE separation, SMALL molecules, MOLECULAR structure, CONJUGATED polymers, PHOTOVOLTAIC cells, SILICON solar cells, FULLERENE polymers

Abstract

Compared to conjugated polymers, small‐molecule organic semiconductors present negligible batch‐to‐batch variations, but presently provide comparatively low power conversion efficiencies (PCEs) in small‐molecular organic solar cells (SM‐OSCs), mainly due to suboptimal nanomorphology. Achieving precise control of the nanomorphology remains challenging. Here, two new small‐molecular donors H13 and H14, created by fluorine and chlorine substitution of the original donor molecule H11, are presented that exhibit a similar or higher degree of crystallinity/aggregation and improved open‐circuit voltage with IDIC‐4F as acceptor. Due to kinetic and thermodynamic reasons, H13‐based blend films possess relatively unfavorable molecular packing and morphology. In contrast, annealed H14‐based blends exhibit favorable characteristics, i.e., the highest degree of aggregation with the smallest paracrystalline π–π distortions and a nanomorphology with relatively pure domains, all of which enable generating and collecting charges more efficiently. As a result, blends with H13 give a similar PCE (10.3%) as those made with H11 (10.4%), while annealed H14‐based SM‐OSCs have a significantly higher PCE (12.1%). Presently this represents the highest efficiency for SM‐OSCs using IDIC‐4F as acceptor. The results demonstrate that precise control of phase separation can be achieved by fine‐tuning the molecular structure and film formation conditions, improving PCE and providing guidance for morphology design. [ABSTRACT FROM AUTHOR]

Published

2020

9. Unifying Charge Generation, Recombination, and Extraction in Low‐Offset Non‐Fullerene Acceptor Organic Solar Cells.

Author

Karki, Akchheta, Vollbrecht, Joachim, Gillett, Alexander J., Selter, Philipp, Lee, Jaewon, Peng, Zhengxing, Schopp, Nora, Dixon, Alana L., Schrock, Max, Nádaždy, Vojtech, Schauer, Franz, Ade, Harald, Chmelka, Bradley F., Bazan, Guillermo C., Friend, Richard H., and Nguyen, Thuc‐Quyen

Subjects

SOLAR cells, SILICON solar cells, SOFT X rays, X-ray scattering, DECONVOLUTION (Mathematics), HETEROJUNCTIONS

Abstract

Even though significant breakthroughs with over 18% power conversion efficiencies (PCEs) in polymer:non‐fullerene acceptor (NFA) bulk heterojunction organic solar cells (OSCs) have been achieved, not many studies have focused on acquiring a comprehensive understanding of the underlying mechanisms governing these systems. This is because it can be challenging to delineate device photophysics in polymer:NFA blends comprehensively, and even more complicated to trace the origins of the differences in device photophysics to the subtle differences in energetics and morphology. Here, a systematic study of a series of polymer:NFA blends is conducted to unify and correlate the cumulative effects of i) voltage losses, ii) charge generation efficiencies, iii) non‐geminate recombination and extraction dynamics, and iv) nuanced morphological differences with device performances. Most importantly, a deconvolution of the major loss processes in polymer:NFA blends and their connections to the complex BHJ morphology and energetics are established. An extension to advanced morphological techniques, such as solid‐state NMR (for atomic level insights on the local ordering and donor:acceptor ππ interactions) and resonant soft X‐ray scattering (for donor and acceptor interfacial area and domain spacings), provide detailed insights on how efficient charge generation, transport, and extraction processes can outweigh increased voltage losses to yield high PCEs. [ABSTRACT FROM AUTHOR]

Published

2020

10. High‐Performance Tandem Organic Solar Cells Using HSolar as the Interconnecting Layer.

Author

Ho, Carr Hoi Yi, Kim, Taesoo, Xiong, Yuan, Firdaus, Yuliar, Yi, Xueping, Dong, Qi, Rech, Jeromy J., Gadisa, Abay, Booth, Ronald, O'Connor, Brendan T., Amassian, Aram, Ade, Harald, You, Wei, Anthopoulos, Thomas D., and So, Franky

Subjects

SOLAR cells, PHOTOVOLTAIC cells, SILICON solar cells, EFFICIENCY of photovoltaic cells

Abstract

Tandem structure provides a practical way to realize high efficiency organic photovoltaic cells, it can be used to extend the wavelength coverage for light harvesting. The interconnecting layer (ICL) between subcells plays a critical role in the reproducibility and performance of tandem solar cells, yet the processability of the ICL has been a challenge. In this work the fabrication of highly reproducible and efficient tandem solar cells by employing a commercially available material, PEDOT:PSS HTL Solar (HSolar), as the hole transporting material used for the ICL is reported. Comparing with the conventional PEDOT:PSS Al 4083 (c‐PEDOT), HSolar offers a better wettability on the underlying nonfullerene photoactive layers, resulting in better charge extraction properties of the ICL. When FTAZ:IT‐M and PTB7‐Th:IEICO‐4F are used as the subcells, a power conversion efficiency (PCE) of 14.7% is achieved in the tandem solar cell. To validate the processability of these tandem solar cells, three other research groups have successfully fabricated tandem devices using the same recipe and the highest PCE obtained is 16.1%. With further development of donor polymers and device optimization, the device simulation results show that a PCE > 22% can be realized in tandem cells in the near future. [ABSTRACT FROM AUTHOR]

Published

2020

11. Balanced Charge Transport Optimizes Industry‐Relevant Ternary Polymer Solar Cells.

Author

Szymanski, Robin, Henry, Reece, Stuard, Samuel, Vongsaysy, Uyxing, Courtel, Stéphanie, Vellutini, Luc, Bertrand, Mélanie, Ade, Harald, Chambon, Sylvain, and Wantz, Guillaume

Subjects

SOLAR cells, CHARGE carrier mobility, POLYMERS, SILICON solar cells

Published

2020

12. Organic Solar Cells: High‐Performance Tandem Organic Solar Cells Using HSolar as the Interconnecting Layer (Adv. Energy Mater. 25/2020).

Author

Ho, Carr Hoi Yi, Kim, Taesoo, Xiong, Yuan, Firdaus, Yuliar, Yi, Xueping, Dong, Qi, Rech, Jeromy J., Gadisa, Abay, Booth, Ronald, O'Connor, Brendan T., Amassian, Aram, Ade, Harald, You, Wei, Anthopoulos, Thomas D., and So, Franky

Subjects

SOLAR cells, SILICON solar cells, PHOTOVOLTAIC power generation

Abstract

Organic Solar Cells: High-Performance Tandem Organic Solar Cells Using HSolar as the Interconnecting Layer (Adv. Keywords: interconnecting layers; organic photovoltaics; tandem solar cells EN interconnecting layers organic photovoltaics tandem solar cells 1 1 1 07/09/20 20200707 NES 200707 In article number 2000823, Carr Hoi Yi Ho, Franky So and co-workers presented a simple yet highly compatible interconnecting layer for organic tandem solar cells. In addition, most of the tandem devices achieve more than 40% enhancement from the single-junction solar cell. [Extracted from the article]

Published

2020

13. Reduced Nonradiative Energy Loss Caused by Aggregation of Nonfullerene Acceptor in Organic Solar Cells.

Author

Qin, Yunpeng, Zhang, Shaoqing, Xu, Ye, Ye, Long, Wu, Yi, Kong, Jingyi, Xu, Bowei, Yao, Huifeng, Ade, Harald, and Hou, Jianhui

Subjects

SOLAR cells, ENERGY dissipation, OPEN-circuit voltage, SILICON solar cells, PHOTOVOLTAIC cells, HETEROJUNCTIONS

Abstract

Reducing energy loss (Eloss) is of critical importance to improving the photovoltaic performance of organic solar cells (OSCs). Although nonradiative recombination (Elossnonrad) is investigated in quite a few works, the method for modulating Elossnonrad is seldom reported. Here, a new method of depressing Eloss is reported for nonfullerene OSCs. In addition to ternary‐blend bulk heterojunction (BHJ) solar cells, it is proved that a small molecular material (NRM‐1) can be selectively dispersed into the acceptor phase in the PBDB‐T:IT‐4F‐based OSC, resulting in lower Elossrad and Elossnonrad, and hence a significant improvement in the open‐circuit voltage (VOC); under an optimal feed ratio of NRM‐1, an enhanced power conversion efficiency can also be gained. Moreover, the role of NRM‐1 in the method is illustrated and its applicability for several other representative OSCs is validated. This work paves a new pathway to reduce the Eloss for nonfullerene OSCs. [ABSTRACT FROM AUTHOR]

Published

2019

14. Efficient DPP Donor and Nonfullerene Acceptor Organic Solar Cells with High Photon‐to‐Current Ratio and Low Energetic Loss.

Author

Song, Xin, Gasparini, Nicola, Nahid, Masrur Morshed, Paleti, Sri Harish Kumar, Li, Cheng, Li, Weiwei, Ade, Harald, and Baran, Derya

Subjects

SOLAR cells, PHOTOVOLTAIC cells, SILICON solar cells, QUANTUM efficiency, ELECTROPHILES, SMALL molecules

Abstract

The high crystallinity and ability to harvest near‐infrared photons make diketopyrrolopyrrole (DPP)‐based polymers one of the most promising donors for high performing organic solar cells (OSCs). However, DPP‐based OSC devices still suffer from the trade‐off between energetic loss (Eloss) and maximum external quantum efficiency (EQEmax), which significantly hinders their potential. Thus far, the replacement of fullerenes with small molecule acceptors did not wisdom the performance development of DPP‐donor‐based solar cells due to severe charge recombination issues. In this work, efficient DPP‐based solar cells are reported using low bandgap fused ring electron acceptor, IEICO‐4F. PBDTT‐DPP:IEICO‐4F OSC devices deliver a champion power conversion efficiency of 9.66% with successful interface engineering along with low Eloss of 0.57 eV and a high EQEmax (>70%). [ABSTRACT FROM AUTHOR]

Published

2019

15. Quantifying and Understanding Voltage Losses Due to Nonradiative Recombination in Bulk Heterojunction Organic Solar Cells with Low Energetic Offsets.

Author

Rosenthal, Katie D., Hughes, Michael P., Luginbuhl, Benjamin R., Ran, Niva A., Karki, Akchheta, Ko, Seo‐Jin, Hu, Huawei, Wang, Ming, Ade, Harald, and Nguyen, Thuc‐Quyen

Subjects

SILICON solar cells, SOLAR cells, HETEROJUNCTIONS, OPEN-circuit voltage, ELECTRIC potential, PHOTOVOLTAIC power generation

Abstract

Open‐circuit voltage (VOC) losses in organic photovoltaics (OPVs) inhibit devices from reaching VOC values comparable to the bandgap of the donor–acceptor blend. Specifically, nonradiative recombination losses (∆Vnr) are much greater in OPVs than in silicon or perovskite solar cells, yet the origins of this are not fully understood. To understand what makes a system have high or low loss, an investigation of the nonradiative recombination losses in a total of nine blend systems is carried out. An apparent relationship is observed between the relative domain purity of six blends and the degree of nonradiative recombination loss, where films exhibiting relatively less pure domains show lower ∆Vnr than films with higher domain purity. Additionally, it is shown that when paired with a fullerene acceptor, polymer donors which have bulky backbone units to inhibit close π–π stacking exhibit lower nonradiative recombination losses than in blends where the polymer can pack more closely. This work reports a strategy that ensures ∆Vnr can be measured accurately and reports key observations on the relationship between ∆Vnr and properties of the donor/acceptor interface. [ABSTRACT FROM AUTHOR]

Published

2019

16. Rational Strategy to Stabilize an Unstable High‐Efficiency Binary Nonfullerene Organic Solar Cells with a Third Component.

Author

Zhu, Youqin, Gadisa, Abay, Peng, Zhengxing, Ghasemi, Masoud, Ye, Long, Xu, Zheng, Zhao, Suling, and Ade, Harald

Subjects

SILICON solar cells, SOLAR cells, MISCIBILITY, CELL anatomy, SOLAR technology, PERCOLATION, THERMODYNAMICS

Abstract

Long device lifetime is still a missing key requirement in the commercialization of nonfullerene acceptor (NFA) organic solar cell technology. Understanding thermodynamic factors driving morphology degradation or stabilization is correspondingly lacking. In this report, thermodynamics is combined with morphology to elucidate the instability of highly efficient PTB7‐Th:IEICO‐4F binary solar cells and to rationally use PC71BM in ternary solar cells to reduce the loss in the power conversion efficiency from ≈35% to <10% after storage for 90 days and at the same time improve performance. The hypomiscibility observed for IEICO‐4F in PTB7‐Th (below the percolation threshold) leads to overpurification of the mixed domains. By contrast, the hypermiscibility of PC71BM in PTB7‐Th of 48 vol% is well above the percolation threshold. At the same time, PC71BM is partly miscible in IEICO‐4F suppressing crystallization of IEICO‐4F. This work systematically illustrates the origin of the intrinsic degradation of PTB7‐Th:IEICO‐4F binary solar cells, demonstrates the structure–function relations among thermodynamics, morphology, and photovoltaic performance, and finally carries out a rational strategy to suppress the degradation: the third component needs to have a miscibility in the donor polymer at or above the percolation threshold, yet also needs to be partly miscible with the crystallizable acceptor. [ABSTRACT FROM AUTHOR]

Published

2019