Understanding the Impact of Hierarchical Nanostructure in Ternary Organic Solar Cells

Fang, Jin; Wang, Zaiyu; Zhang, Jianqi; Zhang, Yajie; Deng, Dan; Wang, Zhen; Lü, Kun; Ma, Wei; Wei, Zhixiang

doi:10.1002/advs.201500250

Cited by 43 publications

(43 citation statements)

References 56 publications

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“…[9][10][11][12][13] Therefore, compared with the corresponding binary systems, TSCs have the potential to achieve higher light-harvesting and/or improved charge transport, leading to increased J sc and/or FF. [14][15][16] However, it should be noted that the emission of the third component and the absorption of the donor or acceptor must overlap in order to get efficient energy transfer. In addition, the morphology tuning highly depends on the crystallinity and miscibility properties of the materials involved.…”

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confidence: 99%

Combining Energy Transfer and Optimized Morphology for Highly Efficient Ternary Polymer Solar Cells

Zhao

Wang

et al. 2017

Advanced Energy Materials

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photovoltaic performance, as they not only maintain the simple device configuration and low-cost processing of single-junction polymer solar cells (PSCs), but also inherit the major benefit of incorporating multiple polymers in tandem cells. [1][2][3] In general, the third component mainly plays a role in energy transfer or electron transfer on the condition of proper cascaded energy levels, which lead to an increase in shortcircuit current density (J sc ) by extended absorption and more efficient charge generation. [2,[4][5][6] Besides, the third component with relatively high crystallinity may also act as a template to facilitate supramolecular assembly for achieving ideal morphology of active layer, [2,7,8,4] providing numerous D/A area for exciton dissociation and affording optimized phase separation to facilitate the charge transport. [9][10][11][12][13] Therefore, compared with the corresponding binary systems, TSCs have the potential to achieve higher light-harvesting and/or improved charge transport, leading to increased J sc and/or FF. [14][15][16] However, it should be noted that the emission of the third component and the absorption of the donor or acceptor must overlap in order to get efficient energy transfer. In addition, the morphology tuning highly depends on the crystallinity and miscibility properties of the materials involved. Unfortunately for ternary systems, Aimed at achieving ideal morphology, illuminating morphology-performance relationship, and further improving the power conversion efficiency (PCE) of ternary polymer solar cells (TSCs), a ternary system is designed based on PTB7-Th:PffBT4T-2OD:PC 71 BM in this work. The PffBT4T-2OD owns large absorption cross section, proper energy levels, and good crystallinity, which enhances exciton generation, charge dissociation and transport and suppresses charge recombination, thus remarkably increasing the short-circuit current density (J sc ) and fill factor (FF). Finally, a notable PCE of 10.72% is obtained for the TSCs with 15% weight ratio of PffBT4T-2OD. As for the working mechanism, it confirmed the energy transfer from PffBT4T-2OD to PTB7-Th, which contributes to the improved exciton generation. And morphology characterization indicates that the devices with 15% PffBT4T-2OD possess both appropriate domain size (25 nm) and enhanced domain purity. Under this condition, it affords numerous D/A interface for exciton dissociation and good bicontinuous nanostructure for charge transport simultaneously. As a result, the device with 15% PffBT4T-2OD exhibits improved exciton generation, enhanced charge dissociation possibility, elevated hole mobility and inhibited charge recombination, leading to elevated J sc (19.02 mA cm −2 ) and FF (72.62%) simultaneously. This work indicates that morphology optimization as well as energy transfer plays a significant role in improving TSC performance.

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confidence: 99%

Combining Energy Transfer and Optimized Morphology for Highly Efficient Ternary Polymer Solar Cells

Zhao

Wang

et al. 2017

Advanced Energy Materials

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“…The resulting changes in film morphology, i.e., high crystallinity and appropriate phase separation, boosted the PCE from 6.85% to 8.40%. Similar phenomena were observed when BDT‐3T‐CNCOO was added to a PBDTTT‐C‐T:PC 70 BM blend: the domain size and purity are increased when 50% BDT‐3T‐CNCOO is incorporated; moreover, the presence of BDT‐3T‐CNCOO induces the formation of nanofibrous polymer domains that facilitate charge transport . Huang et al incorporated 2,4‐bis[4‐( N , N ‐diisobutylamino)‐2,6‐dihydroxyphenyl] squaraine (SQ) into a P3HT:PC 60 BM blend and found that it broadens the spectral absorption and induces the formation of a nanomorphology .…”

Section: Morphology Controlmentioning

confidence: 68%

Recent Advances in Morphology Optimization for Organic Photovoltaics

et al. 2018

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Organic photovoltaics are an important part of a next-generation energy-harvesting technology that uses a practically infinite pollutant-free energy source. They have the advantages of light weight, solution processability, cheap materials, low production cost, and deformability. However, to date, the moderate photovoltaic efficiencies and poor stabilities of organic photovoltaics impede their use as replacements for inorganic photovoltaics. Recent developments in bulk-heterojunction organic photovoltaics mean that they have almost reached the lower efficiency limit for feasible commercialization. In this review article, the recent understanding of the ideal bulk-heterojunction morphology of the photoactive layer for efficient exciton dissociation and charge transport is described, and recent attempts as well as early-stage trials to realize this ideal morphology are discussed systematically from a morphological viewpoint. The various approaches to optimizing morphologies consisting of an interpenetrating bicontinuous network with appropriate domain sizes and mixed regions are categorized, and in each category, the recent trends in the morphology control on the multilength scale are highlighted and discussed in detail. This review article concludes by identifying the remaining challenges for the control of active layer morphologies and by providing perspectives toward real application and commercialization of organic photovoltaics.

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“…Generally, a ternary blend has one additional electron donor or acceptor material compared with its binary counterpart. In addition to complementary absorption with respect to the binary blend, the third component also plays a very important role in tuning the morphology of the active layer though molecular interactions between the donors and acceptors, resulting in pure domains, face‐on orientations, and higher crystallinity, which are beneficial for exciton dissociation and charge transport . As a consequence, the J sc and FF are improved for ternary OSCs.…”

Section: Current Status Of Organic Solar Cellsmentioning

confidence: 99%

Toward Over 15% Power Conversion Efficiency for Organic Solar Cells: Current Status and Perspectives

2017

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Significant improvement in the power conversion efficiency (PCE) of organic solar cells (OSCs) is achieved by developing novel donor and acceptor materials, optimizing the phase‐separation morphology via diversified strategies, and using interfacial materials for better charge‐carrier collection. For state‐of‐the‐art devices, a PCE of over 13% is reported. However, simulations indicate that an efficiency of ≈19% could be realized, assuming a total energy loss of 0.5 eV with an external quantum efficiency of 90% and a fill factor of 70%. This large difference between the theoretical calculations and the actual performance of the state‐of‐the‐art devices shows that OSCs have significant potential for the future. Here, the energy loss is discussed, which determines the PCE limit, and then different systems are reviewed, such as small‐molecule (SM)/fullerene blends, polymer/fullerene blends, SM/nonfullerene blends, polymer/nonfullerene blends, and multicomponent systems. After highlighting the factors that have limited the device efficiency to date, an outlook on the most important challenges to guide OSCs toward the 15% PCE regime is provided.

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Understanding the Impact of Hierarchical Nanostructure in Ternary Organic Solar Cells

Cited by 43 publications

References 56 publications

Combining Energy Transfer and Optimized Morphology for Highly Efficient Ternary Polymer Solar Cells

Combining Energy Transfer and Optimized Morphology for Highly Efficient Ternary Polymer Solar Cells

Recent Advances in Morphology Optimization for Organic Photovoltaics

Toward Over 15% Power Conversion Efficiency for Organic Solar Cells: Current Status and Perspectives

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