Ladder‐Type Heteroheptacenes with Different Heterocycles for Nonfullerene Acceptors

Ma, Yunlong; Cai, Dongdong; Wan, Shuo; Wang, Pengsong; Wang, Jin-Yun; Zheng, Qingdong

doi:10.1002/anie.202007907

Cited by 117 publications

(85 citation statements)

References 34 publications

(69 reference statements)

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“…We also calculated the HOMA (harmonic oscillator model of aromaticity) value of individual rings for three different heteroheptacene cores (Figure S2). According to the sum of ∑ HOMA values, the global aromaticity of the three cores can be estimated, [29] and their ∑ HOMA indices are basically the same (5.34, 5.30, and 5.28 for MQ3, MQ5, and MQ6, respectively) although the incorporation of selenophene heterocycles did lead to slightly decreased global aromaticity, as expected, in comparison with that based on thiophene heterocycles (5.694 for M34) [23a] . Especially, the switch of selenium atoms in the outer and inner positions of the heteroheptacene cores barely changes their ∑ HOMA indices.…”

Section: Resultssupporting

confidence: 56%

High‐Performance Ladder‐Type Heteroheptacene‐Based Nonfullerene Acceptors Enabled by Asymmetric Cores with Enhanced Noncovalent Intramolecular Interactions

et al. 2021

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Nonfullerene acceptors (MQ3, MQ5, MQ6) are synthesized using asymmetric and symmetric ladder‐type heteroheptacene cores with selenophene heterocycles. Although MQ3 and MQ5 are constructed with the same number of selenophene heterocycles, the heteroheptacene core of MQ5 is end‐capped with selenophene rings while that of MQ3 is flanked with thiophene rings. With the enhanced noncovalent interaction of O⋅⋅⋅Se compared to that of O⋅⋅⋅S, MQ5 shows a bathochromically shifted absorption band and greatly improved carrier transport, leading to a higher power conversion efficiency (PCE) of 15.64 % compared to MQ3, which shows a PCE of 13.51 %. Based on the asymmetric heteroheptacene core, MQ6 shows an improved carrier transport induced by the reduced π–π stacking distance, related with the increased dipole moment in comparison with the nonfullerene acceptors based on symmetric cores. MQ6 exhibits a PCE of 16.39 % with a VOC of 0.88 V, a FF of 75.66 %, and a JSC of 24.62 mA cm−2.

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Section: Resultssupporting

confidence: 56%

High‐Performance Ladder‐Type Heteroheptacene‐Based Nonfullerene Acceptors Enabled by Asymmetric Cores with Enhanced Noncovalent Intramolecular Interactions

et al. 2021

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“…[1][2][3][4][5][6][7][8] Since Zhan and co-workers developed ITIC [9] and its derivatives [10][11][12][13] as electron acceptors for BHJ OSCs in 2015, fused ring electron acceptors (FREAs) have replaced the fullerenes to dominate electron acceptors in organic photovoltaics and then greatly boost the development on efficiency and stability of OSCs. Until now, the power conversion efficiencies (PCEs) of OSCs employing high performance polymer donors (like PM6, [14] PM7, [15] D18, [16] and PM6-Tz20 [17] ) and FREAs (such as Y6, [18] M34, [19] and BTP-4Cl [20] ) have reached over 16-17% for single-junction OSCs. However, the device efficiency of OSCs is still much lower than those of inorganic/hybrid solar cells, such as crystalline silicon, [21] and hybrid perovskite.…”

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confidence: 99%

An Electron Acceptor Analogue for Lowering Trap Density in Organic Solar Cells

et al. 2021

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Typical organic semiconductor materials exhibit a high trap density of states, ranging from 1016 to 1018 cm−3, which is one of the important factors in limiting the improvement of power conversion efficiencies (PCEs) of organic solar cells (OSCs). In order to reduce the trap density within OSCs, a new strategy to design and synthesize an electron acceptor analogue, BTPR, is developed, which is introduced into OSCs as a third component to enhance the molecular packing order of electron acceptor with and without blending a polymer donor. Finally, the as‐cast ternary OSC devices employing BTPR show a notable PCE of 17.8%, with a low trap density (1015 cm−3) and a low energy loss (0.217 eV) caused by non‐radiative recombination. This PCE is among the highest values for single‐junction OSCs. The trap density of OSCs with the BTPR additives, as low as 1015 cm−3, is comparable to and even lower than those of several typical high‐performance inorganic/hybrid counterparts, like 1016 cm−3 for amorphous silicon, 1016 cm−3 for metal oxides, and 1014 to 1015 cm−3 for halide perovskite thin film, and makes it promising for OSCs to obtain a PCE of up to 20%.

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“…The dialdehyde intermediate BDTPT‐CHO was synthesized according to the procedure reported by us previously. [ 32 ] Condensation reactions between BDTPT‐CHO and INCN, INCN2Cl, and INCN2Br in chloroform afforded the corresponding acceptors M5, M6, and M7 in 82%, 85%, and 84% yields, respectively. All the acceptors were characterized by 1 H NMR, 13 C NMR, elemental analysis and high‐resolution mass spectrometry (Supporting Information).…”

Section: Resultsmentioning

confidence: 99%

“…Very recently, our group reported a novel type of ladder‐type heteroheptacene cores which are free of the sp 3 ‐hybridized bridging carbons. [ 32–35 ] The aggregation and crystalline properties of these heteroheptacene‐based nonfullerene acceptors can be controlled by modulating the size of the neighboring side‐chains as well as the aromaticity (aromatic stabilization energy) of the heteroheptacene core. Through reducing the ππ interaction (or stacking) distance, the resulting nonfullerene acceptor (M36) showed enhanced charge transport and therefore a greatly boosted PCE of 16%, demonstrating the great potential of these ladder‐type heteroheptacene cores for efficient nonfullerene acceptors.…”

Section: Introductionmentioning

confidence: 99%

Enhancing the Photovoltaic Performance of Ladder‐Type Heteroheptacene‐based Nonfullerene Acceptors by Incorporating Halogen Atoms on Their Ending Groups

Wan

Cai

et al. 2021

Adv Funct Materials

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Ending group halogenation is an effective strategy for modulating the energy levels, bandgaps, and intermolecular interactions of nonfullerene acceptors. Understanding the influence of different halogen atoms on the acceptor properties is of great importance for designing high‐performance nonfullerene acceptors. Here, three acceptor–donor–acceptor (A‐D‐A) type nonfullerene acceptors (M5, M6, and M7), which are constructed by using a ladder‐type heteroheptacene core without the traditional sp3 carbon‐bonded side chains as the electron‐rich core, and 2‐(3‐oxo‐2,3‐dihydro‐1H‐inden‐1‐ylidene)malononitrile without or with halogen atoms as the ending groups. The nonfullerene acceptors with chlorinated (M6) and brominated (M7) ending groups exhibit broadened absorption spectra, down‐shifted energy levels, and enhanced molecular ordering compared to the counterpart without any halogenated ending groups (M5). Among the nonfullerene acceptors, M6 has the strongest intermolecular ππ interaction with its shortest ππ interaction distance and the longest coherent length which are beneficial for enhancing the charge transport and therefore boosting the photovoltaic performance. An excellent power conversion efficiency of 15.45% is achieved for the best‐performing polymer solar cell based on M6. These results suggest that the halogenated ending groups are essential for high‐performance heteroheptacene‐based nonfullerene acceptors considering their simultaneous enhancements in both the light‐harvesting and the charge transport.

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Ladder‐Type Heteroheptacenes with Different Heterocycles for Nonfullerene Acceptors

Cited by 117 publications

References 34 publications

High‐Performance Ladder‐Type Heteroheptacene‐Based Nonfullerene Acceptors Enabled by Asymmetric Cores with Enhanced Noncovalent Intramolecular Interactions

High‐Performance Ladder‐Type Heteroheptacene‐Based Nonfullerene Acceptors Enabled by Asymmetric Cores with Enhanced Noncovalent Intramolecular Interactions

An Electron Acceptor Analogue for Lowering Trap Density in Organic Solar Cells

Enhancing the Photovoltaic Performance of Ladder‐Type Heteroheptacene‐based Nonfullerene Acceptors by Incorporating Halogen Atoms on Their Ending Groups

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