New Random Copolymer Acceptors Enable Additive-Free Processing of 10.1% Efficient All-Polymer Solar Cells with Near-Unity Internal Quantum Efficiency

Kolhe, Nagesh B.; Tran, Duyen K.; Lee, Hyun-Jong; Kuzuhara, Daiki; Yoshimoto, Noriyuki; Koganezawa, Tomoyuki; Jenekhe, Samson A.

doi:10.1021/acsenergylett.9b00460

Cited by 131 publications

(121 citation statements)

References 61 publications

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“…Figure summarizes the representative high‐performance polymer acceptors enabling PCEs over 8% in all‐PSCs reported in literature together with their optical bandgap ( E g opt ) and absorption coefficient (ε) . Recently, with the extensive efforts dedicated to polymer design and device optimization, Huang and co‐workers and Jenekhe and co‐workers have achieved all‐PSC performance with PCE greater than 10% using poly(naphthelene diimide‐ alt ‐bithiophene) (N2200) and BSS10 as the acceptor, respectively (Figure a). However, most of the NDI‐ and PDI‐based polymer acceptors exhibit ε values about 3.0–4.8 × 10 4 cm −1 , which are greatly lower than those (1.0–1.3 × 10 5 cm −1 ) of typical nonfullerene small molecules .…”

Section: Figurementioning

confidence: 92%

“…Organic solar cells (OSCs) have achieved long‐term and consistent advance with remarkable power conversion efficiencies (PCEs) of greater than 16% obtained in nonfullerene solar cells, recently . Among various types of OSCs, all‐polymer solar cells (all‐PSCs) consisting of polymers as both donor and acceptor semiconductors show pronounced advantages over other types of OSCs in terms of mechanical flexibility and remarkable device stability . However, the PCEs of all‐PSCs still lag behind those of OSCs based on fullerenes and nonfullerene small molecule acceptors, which is mainly due to the lack of high‐performance n‐type polymer semiconductors.…”

Section: Figurementioning

confidence: 99%

“…The relatively wide bandgap and small absorption coefficient are the long‐standing bottlenecks, which constrain all‐PSC device performance. Figure summarizes the representative high‐performance polymer acceptors enabling PCEs over 8% in all‐PSCs reported in literature together with their optical bandgap ( E g opt ) and absorption coefficient (ε) . Recently, with the extensive efforts dedicated to polymer design and device optimization, Huang and co‐workers and Jenekhe and co‐workers have achieved all‐PSC performance with PCE greater than 10% using poly(naphthelene diimide‐ alt ‐bithiophene) (N2200) and BSS10 as the acceptor, respectively (Figure a).…”

Section: Figurementioning

confidence: 99%

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A Narrow‐Bandgap n‐Type Polymer Semiconductor Enabling Efficient All‐Polymer Solar Cells

et al. 2019

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Currently, n‐type acceptors in high‐performance all‐polymer solar cells (all‐PSCs) are dominated by imide‐functionalized polymers, which typically show medium bandgap. Herein, a novel narrow‐bandgap polymer, poly(5,6‐dicyano‐2,1,3‐benzothiadiazole‐alt‐indacenodithiophene) (DCNBT‐IDT), based on dicyanobenzothiadiazole without an imide group is reported. The strong electron‐withdrawing cyano functionality enables DCNBT‐IDT with n‐type character and, more importantly, alleviates the steric hindrance associated with typical imide groups. Compared to the benchmark poly(naphthalene diimide‐alt‐bithiophene) (N2200), DCNBT‐IDT shows a narrower bandgap (1.43 eV) with a much higher absorption coefficient (6.15 × 104 cm−1). Such properties are elusive for polymer acceptors to date, eradicating the drawbacks inherited in N2200 and other high‐performance polymer acceptors. When blended with a wide‐bandgap polymer donor, the DCNBT‐IDT‐based all‐PSCs achieve a remarkable power conversion efficiency of 8.32% with a small energy loss of 0.53 eV and a photoresponse of up to 870 nm. Such efficiency greatly outperforms those of N2200 (6.13%) and the naphthalene diimide (NDI)‐based analog NDI‐IDT (2.19%). This work breaks the long‐standing bottlenecks limiting materials innovation of n‐type polymers, which paves a new avenue for developing polymer acceptors with improved optoelectronic properties and heralds a brighter future of all‐PSCs.

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Section: Figurementioning

confidence: 92%

Section: Figurementioning

confidence: 99%

Section: Figurementioning

confidence: 99%

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A Narrow‐Bandgap n‐Type Polymer Semiconductor Enabling Efficient All‐Polymer Solar Cells

et al. 2019

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“…Several other NDI‐based polymer acceptors were also used for additive‐free all‐PSCs with their device performance parameters summarized in Table . Recently, random copolymerization has been developed as a simple and effective approach to balance various properties of the NDI‐based polymer acceptors from absorption to energy levels and to blend film morphology, exemplified by polymer BSS10 ( 6.3 ), in which two donor units selenophene and biselenophene with a ratio of 1 : 9 were polymerized with NDI to afford the random copolymer . It demonstrated that with a small ratio of selenophene, the polymer chains showed a face‐on predominant orientation, which can promote more efficient charge transport in solar cell devices.…”

Section: Polymer Acceptors For Additive‐free Oscsmentioning

confidence: 99%

Additive‐Free Non‐Fullerene Organic Solar Cells

et al. 2019

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With the extensive research efforts paid over the past 30 years, the power conversion efficiency of organic solar cells (OSCs) has been steadily improved from below 1 % to greater than 16 %. While fullerene derivatives have traditionally played a dominant role as acceptor materials in the first two decades, the distinctive advantages of non‐fullerene acceptors, such as tunable energy levels, broad absorption, and improved device stability, have rendered them as the mainstream acceptors in OSCs, recently. However, in most cases, processing additives are required for morphology optimization of the photoactive layer, and these additives usually possess high boiling point, which makes it difficult to remove them completely. The residual additives would accelerate performance deterioration, leading to poor device stability. Furthermore, the tedious optimization of additives complicates device fabrication and decreases performance reproducibility. In this review, we summarize the recent works based on non‐fullerene OSCs without using additives, affording insights into materials design and device fabrication for enabling highly efficient additive‐free non‐fullerene OSCs, which should be critical for the practical applications of OSCs.

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“…Thus, all-polymer solar cells (all-PSCs) consisting of a polymeric donor and acceptor have attracted more and more attention and are promising for use in realizing highly efficient and stable solar cells (Kim et al, 2015;Kang et al, 2016;Liu et al, 2016Liu et al, , 2018bLong et al, 2016;Wang et al, 2017;Zhang et al, 2017). Encouragingly, all-PSCs have recently achieved over 10% PCEs (Fan et al, 2017a(Fan et al, ,b, 2018(Fan et al, , 2019bLi et al, 2017a;Zhang et al, 2017;Chen et al, 2018;Kolhe et al, 2019;Li Z. et al, 2019;Meng et al, 2019;Yao et al, 2019;Zhu et al, 2019;Zhao et al, 2020). To date, highly efficient all-PSCs are mostly based on naphthalene diimide (NDI) polymer acceptors, because of their high electron mobility, suitable energy levels, and tunable BHJ morphology Li et al, 2016;Fan et al, 2017a,b;Liu et al, 2018b).…”

Section: Introductionmentioning

confidence: 99%

Ternary All-Polymer Solar Cells With 8.5% Power Conversion Efficiency and Excellent Thermal Stability

et al. 2020

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All-polymer solar cells (all-PSCs) composed of polymer donors and acceptors have attracted widespread attention in recent years. However, the broad and efficient photon utilization of polymer:polymer blend films remains challenging. In our previous work, we developed NOE10, a linear oligoethylene oxide (OE) side-chain modified naphthalene diimide (NDI)-based polymer acceptor which exhibited a power conversion efficiency (PCE) of 8.1% when blended with a wide-bandgap polymer donor PBDT-TAZ. Herein, we report a ternary all-PSC strategy of incorporating a state-of-the-art narrow bandgap polymer (PTB7-Th) into the PBDT-TAZ:NOE10 binary system, which enables 8.5% PCEs within a broad ternary polymer ratio. We further demonstrate that, compared to the binary system, the improved photovoltaic performance of ternary all-PSCs benefits from the combined effect of enhanced photon absorption, more efficient charge generation, and balanced charge transport. Meanwhile, similar to the binary system, the ternary all-PSC also shows excellent thermal stability, maintaining 98% initial PCE after aging for 300 h at 65 • C. This work demonstrates that the introduction of a narrow-bandgap polymer as a third photoactive component into ternary all-PSCs is an effective strategy to realize highly efficient and stable all-PSCs.

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New Random Copolymer Acceptors Enable Additive-Free Processing of 10.1% Efficient All-Polymer Solar Cells with Near-Unity Internal Quantum Efficiency

Cited by 131 publications

References 61 publications

A Narrow‐Bandgap n‐Type Polymer Semiconductor Enabling Efficient All‐Polymer Solar Cells

A Narrow‐Bandgap n‐Type Polymer Semiconductor Enabling Efficient All‐Polymer Solar Cells

Additive‐Free Non‐Fullerene Organic Solar Cells

Ternary All-Polymer Solar Cells With 8.5% Power Conversion Efficiency and Excellent Thermal Stability

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