Non-fullerene acceptors with heteroatom substitution on the core moiety for efficient organic photovoltaics

Feng Qi , Baobing Fan , Qunping Fan , Alex K.-Y. Jen

InfoMat ›› 2024, Vol. 6 ›› Issue (8) : e12595

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InfoMat ›› 2024, Vol. 6 ›› Issue (8) : e12595 DOI: 10.1002/inf2.12595
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Non-fullerene acceptors with heteroatom substitution on the core moiety for efficient organic photovoltaics

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Abstract

Organic photovoltaics (OPVs) represent one of the most promising photovoltaic technologies owing to their high capacity to convert solar energy to electricity. With the continuous structure upgradation of photovoltaic materials, especially that of non-fullerene acceptors (NFAs), the OPV field has witnessed rapid progress with power conversion efficiency (PCE) exceeding 19%. However, it remains challenging to overcome the intrinsic trade-off between the photocurrent and photovoltage, restricting the further promotion of the OPV efficiency. In this regard, it is urgent to further tailor the structure of NFAs to broaden their absorption spectra while mitigating the energy loss of relevant devices concomitantly. Heteroatom substitution on the fused-ring π-core of NFAs is an efficient way to achieve this goal. In addition to improve the near-infrared light harvest by strengthening the intramolecular charge transfer, it can also enhance the molecular stacking via forming multiple noncovalent interactions, which is favorable for reducing the energetic disorder. Therefore, in this review we focus on the design rules of NFAs, including the polymerized NFAs, of which the core moiety is substituted by various kinds of heteroatoms. We also afford a comprehensive understanding on the structure–property–performance relationships of these NFAs. Finally, we anticipate the challenges restricting the efficiency promotion and industrial utilization of OPV, and provide potential solutions based on the further heteroatom optimization on NFA core-moiety.

Keywords

core moiety / heteroatom substitution / near-infrared absorption / non-fullerene acceptor / organic photovoltaics / reduced energy loss

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Feng Qi, Baobing Fan, Qunping Fan, Alex K.-Y. Jen. Non-fullerene acceptors with heteroatom substitution on the core moiety for efficient organic photovoltaics. InfoMat, 2024, 6(8): e12595 DOI:10.1002/inf2.12595

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References

Publishing order | Descend order by publishing year | Descend order by cited within
[1]

Yan C, Barlow S, Wang Z, et al. Non-fullerene acceptors for organic solar cells. Nat Rev Mater. 2018; 3(3): 18003.
[2]

Li Y, Huang X, Sheriff HKM, Forrest SR. Semitransparent organic photovoltaics for building-integrated photovoltaic applications. Nat Rev Mater. 2023; 8(3): 186-201.
[3]

Sun R, Wu Q, Guo J, et al. A layer-by-layer architecture for printable organic solar cells overcoming the scaling lag of module efficiency. Joule. 2020; 4(2): 407-419.
[4]

Zhang G, Lin FR, Qi F, et al. Renewed prospects for organic photovoltaics. Chem Rev. 2022; 122(18): 14180-14274.
[5]

Hou J, Inganäs O, Friend RH, Gao F. Organic solar cells based on non-fullerene acceptors. Nat Mater. 2018; 17(2): 119-128.
[6]

Li C, Zhou J, Song J, et al. Non-fullerene acceptors with branched side chains and improved molecular packing to exceed 18% efficiency in organic solar cells. Nat Energy. 2021; 6(6): 605-613.
[7]

Liu Y, Zhang Z, Feng S, et al. Exploiting noncovalently conformational locking as a design strategy for high performance fused-ring electron acceptor used in polymer solar cells. J Am Chem Soc. 2017; 139(9): 3356-3359.
[8]

Qi F, Li Y, Zhang R, et al. Dimer acceptor adopting a flexible linker for efficient and durable organic solar cells. Angew Chem Int Ed. 2023; 62(21): e202303066.
[9]

Sun C, Qin S, Wang R, et al. High efficiency polymer solar cells with efficient hole transfer at zero highest occupied molecular orbital offset between methylated polymer donor and brominated acceptor. J Am Chem Soc. 2020; 142(3): 1465-1474.
[10]

Lin Y, Wang J, Zhang Z-G, et al. An electron acceptor challenging fullerenes for efficient polymer solar cells. Adv Mater. 2015; 27(7): 1170-1174.
[11]

Yuan J, Zhang Y, Zhou L, et al. Single-junction organic solar cell with over 15% efficiency using fused-ring acceptor with electron-deficient Core. Joule. 2019; 3(4): 1140-1151.
[12]

Zhu C, Yuan J, Cai F, et al. Tuning the electron-deficient core of a non-fullerene acceptor to achieve over 17% efficiency in a single-junction organic solar cell. Energ Environ Sci. 2020; 13(8): 2459-2466.
[13]

Lu H, Liu W, Ran G, et al. High-pressure fabrication of binary organic solar cells with high molecular weight D18 yields record 19.65% efficiency. Angew Chem Int Ed. 2023; 62(50): e202314420.
[14]

Fu J, Yang Q, Huang P, et al. Rational molecular and device design enables organic solar cells approaching 20% efficiency. Nat Commun. 2024; 15(1): 1830.
[15]

Lu H, Liu W, Ran G, et al. High-efficiency binary and ternary organic solar cells based on novel nonfused-ring electron acceptors. Adv Mater. 2024; 36(7): 2307292.
[16]

Qian D, Zheng Z, Yao H, et al. Design rules for minimizing voltage losses in high-efficiency organic solar cells. Nat Mater. 2018; 17(8): 703-709.
[17]

Benduhn J, Tvingstedt K, Piersimoni F, et al. Intrinsic non-radiative voltage losses in fullerene-based organic solar cells. Nat Energy. 2017; 2(6): 17053.
[18]

Chen X-K, Qian D, Wang Y, et al. A unified description of non-radiative voltage losses in organic solar cells. Nat Energy. 2021; 6(8): 799-806.
[19]

Menke SM, Ran NA, Bazan GC, Friend RH. Understanding energy loss in organic solar cells: toward a new efficiency regime. Joule. 2018; 2(1): 25-35.
[20]

Brédas J-L, Norton JE, Cornil J, Coropceanu V. Molecular understanding of organic solar cells: the challenges. Acc Chem Res. 2009; 42(11): 1691-1699.
[21]

Fu Z, Zhang X, Zhang H, Li Y, Zhou H, Zhang Y. On the understandings of dielectric constant and its impacts on the photovoltaic efficiency in organic solar cells. Chin J Chem. 2021; 39(2): 381-390.
[22]

Chen H, Zou Y, Liang H, et al. Lowing the energy loss of organic solar cells by molecular packing engineering via multiple molecular conjugation extension. Sci China Chem. 2022; 65(7): 1362-1373.
[23]

Lai H, Zhao Q, Chen Z, et al. Trifluoromethylation enables a 3D interpenetrated low-band-gap acceptor for efficient organic solar cells. Joule. 2020; 4(3): 688-700.
[24]

Rao A, Chow PCY, Gélinas S, et al. The role of spin in the kinetic control of recombination in organic photovoltaics. Nature. 2013; 500(7463): 435-439.
[25]

Liu S, Yuan J, Deng W, et al. High-efficiency organic solar cells with low non-radiative recombination loss and low energetic disorder. Nat Photon. 2020; 14(5): 300-305.
[26]

Blakesley JC, Neher D. Relationship between energetic disorder and open-circuit voltage in bulk heterojunction organic solar cells. Phys Rev B. 2011; 84(7): 075210.
[27]

Garcia-Belmonte G, Bisquert J. Open-circuit voltage limit caused by recombination through tail states in bulk heterojunction polymer-fullerene solar cells. Appl Phys Lett. 2010; 96(11): 113301.
[28]

Ma Y, Cai D, Wan S, Wang P, Wang J, Zheng Q. Ladder-type heteroheptacenes with different heterocycles for nonfullerene acceptors. Angew Chem Int Ed. 2020; 59(48): 21627-21633.
[29]

Li Y, Zhong L, Wu F-P, et al. Non-fullerene polymer solar cells based on a selenophene-containing fused-ring acceptor with photovoltaic performance of 8.6%. Energy Environ Sci. 2016; 9(11): 3429-3435.
[30]

Xiao Z, Liu F, Geng X, et al. A carbon-oxygen-bridged ladder-type building block for efficient donor and acceptor materials used in organic solar cells. Sci Bull. 2017; 62(19): 1331-1336.
[31]

Yao Z, Cao X, Bi X, et al. Complete peripheral fluorination of the small-molecule acceptor in organic solar cells yields efficiency over 19%. Angew Chem Int Ed. 2023; 62(44): e202312630.
[32]

Fan Q, Fu H, Bai H, et al. NIR-absorbing polymer acceptor for efficient all-polymer solar cells with a record-high photocurrent of 26.5 mA cm–2. DeCarbon. 2023; 2: 100024.
[33]

Yao Z, Liao X, Gao K, et al. Dithienopicenocarbazole-based acceptors for efficient organic solar cells with optoelectronic response over 1000 nm and an extremely low energy loss. J Am Chem Soc. 2018; 140(6): 2054-2057.
[34]

Liu W, Sun S, Zhou L, et al. Design of near-infrared nonfullerene acceptor with ultralow nonradiative voltage loss for high-performance semitransparent ternary organic solar cells. Angew Chem Int Ed. 2022; 61(19): e202116111.
[35]

Wan S-S, Xu X, Jiang Z, et al. A bromine and chlorine concurrently functionalized end group for benzo [1, 2-b:4, 5-b’] diselenophene-based non-fluorinated acceptors: a new hybrid strategy to balance the crystallinity and miscibility of blend films for enabling highly efficient polymer solar cells. J Mater Chem A. 2020; 8(9): 4856-4867.
[36]

Li T, Wu Y, Zhou J, et al. Butterfly effects arising from starting materials in fused-ring electron acceptors. J Am Chem Soc. 2020; 142(47): 20124-20133.
[37]

Qi F, Jones LO, Jiang K, et al. Regiospecific N-alkyl substitution tunes the molecular packing of high-performance non-fullerene acceptors. Mater Horiz. 2022; 9(1): 403-410.
[38]

Fan Q, Lin FR, Ma W, Jen AKY. Selenium-fused Y6 derivatives and their derived polymerized small molecule acceptors for efficient organic solar cells. Sci China Chem. 2022; 66(3): 615-619.
[39]

Qi F, Lin FR, Jen AKY. Selenium: a unique member in the Chalcogen family for conjugated materials used in perovskite and organic solar cells. Solar RRL. 2022; 6(7): 2200156.
[40]

Fan B, Lin F, Wu X, Zhu Z, Jen AKY. Selenium-containing organic photovoltaic materials. Acc Chem Res. 2021; 54(20): 3906-3916.
[41]

Fan B, Gao W, Zhang R, et al. Correlation of broad absorption band with small singlet-triplet energy gap in organic photovoltaics. Angew Chem Int Ed. 2023; 62(46): e202311559.
[42]

Fan B, Gao W, Zhang R, et al. Correlation of local isomerization induced lateral and terminal torsions with performance and stability of organic photovoltaics. J Am Chem Soc. 2023; 145(10): 5909-5919.
[43]

Liang H, Bi X, Chen H, et al. A rare case of brominated small molecule acceptors for high-efficiency organic solar cells. Nat Commun. 2023; 14(1): 4707.
[44]

Huang C, Liao X, Gao K, et al. Highly efficient organic solar cells based on S, N-heteroacene non-fullerene acceptors. Chem Mater. 2018; 30(15): 5429-5434.
[45]

Brédas J-L, Beljonne D, Coropceanu V, Cornil J. Charge-transfer and energy-transfer processes in π-conjugated oligomers and polymers: a molecular picture. Chem Rev. 2004; 104(11): 4971-5004.
[46]

Sun J, Ma X, Zhang Z, et al. Dithieno[3, 2-b:2’ 3’-d]pyrrol fused nonfullerene acceptors enabling over 13% efficiency for organic solar cells. Adv Mater. 2018; 30(16): e1707150.
[47]

Luo Z, Ma R, Yu J, et al. Heteroheptacene-based acceptors with thieno[3, 2-b]pyrrole yield high-performance polymer solar cells. Natl Sci Rev. 2022; 9(7): nwac076.
[48]

Ma Y, Zhang M, Wan S, et al. Efficient organic solar cells from molecular orientation control of M-series acceptors. Joule. 2021; 5(1): 197-209.
[49]

Qi F, Jiang K, Lin F, et al. Over 17% efficiency binary organic solar cells with Photoresponses reaching 1000 nm enabled by selenophene-fused nonfullerene acceptors. ACS Energy Lett. 2020; 6(1): 9-15.
[50]

Fu H, Li Y, Yu J, et al. High efficiency (15.8%) all-polymer solar cells enabled by a regioregular narrow bandgap polymer acceptor. J Am Chem Soc. 2021; 143(7): 2665-2670.
[51]

Du J, Hu K, Zhang J, et al. Polymerized small molecular acceptor based all-polymer solar cells with an efficiency of 16.16% via tuning polymer blend morphology by molecular design. Nat Commun. 2021; 12(1): 5264.
[52]

Sun H, Liu B, Ma Y, et al. Regioregular narrow-bandgap n-type polymers with high electron mobility enabling highly efficient all-polymer solar cells. Adv Mater. 2021; 33(37): e2102635.
[53]

Shi X, Liao X, Gao K, et al. An electron acceptor with broad visible–NIR absorption and unique solid state packing for As-cast high performance binary organic solar cells. Adv Funct Mater. 2018; 28(33): 1802324.
[54]

Lin F, Zuo L, Gao K, et al. Regio-specific selenium substitution in non-fullerene acceptors for efficient organic solar cells. Chem Mater. 2019; 31(17): 6770-6778.
[55]

Bai H, Ma R, Su W, et al. Green-solvent processed blade-coating organic solar cells with an efficiency approaching 19% enabled by alkyl-tailored acceptors. Nanomicro Lett. 2023; 15(1): 241.
[56]

Kang I, An TK, Hong J-a, et al. Effect of selenophene in a DPP copolymer incorporating a vinyl group for high-performance organic field-effect transistors. Adv Mater. 2013; 25(4): 524-528.
[57]

Jin K, Deng C, Zhang L, et al. A heptacyclic carbon–oxygen-bridged ladder-type building block for A–D–A acceptors. Mater Chem Front. 2018; 2(9): 1716-1719.
[58]

Xiao Z, Jia X, Li D, et al. 26 mA cm–2Jsc from organic solar cells with a low-bandgap nonfullerene acceptor. Sci Bull. 2017; 62(22): 1494-1496.
[59]

Qin Y, Chen H, Yao J, et al. Silicon and oxygen synergistic effects for the discovery of new high-performance nonfullerene acceptors. Nat Commun. 2020; 11(1): 5814.
[60]

Li X, Pan F, Sun C, et al. Simplified synthetic routes for low cost and high photovoltaic performance n-type organic semiconductor acceptors. Nat Commun. 2019; 10(1): 519.
[61]

Huang H, Guo Q, Feng S, et al. Noncovalently fused-ring electron acceptors with near-infrared absorption for high-performance organic solar cells. Nat Commun. 2019; 10(1): 3038.
[62]

Yu ZP, Liu ZX, Chen FX, et al. Simple non-fused electron acceptors for efficient and stable organic solar cells. Nat Commun. 2019; 10(1): 2152.
[63]

Zhang X, Li C, Qin L, et al. Side-chain engineering for enhancing the molecular rigidity and photovoltaic performance of noncovalently fused-ring electron acceptors. Angew Chem Int Ed. 2021; 60(32): 17720-17725.
[64]

Wang J-L, Liu K-K, Hong L, Ge G-Y, Zhang C, Hou J. Selenopheno[3, 2-b]thiophene-based narrow-bandgap nonfullerene acceptor enabling 13.3% efficiency for organic solar cells with thickness-insensitive feature. ACS Energy Lett. 2018; 3(12): 2967-2976.
[65]

Lin F, Jiang K, Kaminsky W, Zhu Z, Jen AKY. A non-fullerene acceptor with enhanced intermolecular pi-core interaction for high-performance organic solar cells. J Am Chem Soc. 2020; 142(36): 15246-15251.
[66]

Chai G, Zhang J, Pan M, et al. Deciphering the role of Chalcogen-containing heterocycles in nonfullerene acceptors for organic solar cells. ACS Energy Lett. 2020; 5(11): 3415-3425.
[67]

Zhang Z, Li Y, Cai G, Zhang Y, Lu X, Lin Y. Selenium heterocyclic electron acceptor with small Urbach energy for As-cast high-performance organic solar cells. J Am Chem Soc. 2020; 142(44): 18741-18745.
[68]

Gao W, Qi F, Peng Z, et al. Achieving 19% power conversion efficiency in planar-mixed heterojunction organic solar cells using a Pseudosymmetric electron acceptor. Adv Mater. 2022; 34(32): e2202089.
[69]

Fan Q, Ma R, Yang J, et al. Unidirectional sidechain engineering to construct dual-asymmetric acceptors for 19.23% efficiency organic solar cells with low energy loss and efficient charge transfer. Angew Chem Int Ed. 2023; 62(36): e202308307.
[70]

Yang C, An Q, Bai HR, et al. A synergistic strategy of manipulating the number of selenophene units and dissymmetric central core of small molecular acceptors enables polymer solar cells with 17.5% efficiency. Angew Chem Int Ed. 2021; 60(35): 19241-19252.
[71]

Feng K, Huang J, Zhang X, et al. High-performance all-polymer solar cells enabled by n-type polymers with an ultranarrow bandgap down to 1.28 eV. Adv Mater. 2020; 32(30): e2001476.
[72]

Fan Q, Fu H, Wu Q, et al. Multi-selenophene-containing narrow bandgap polymer acceptors for all-polymer solar cells with over 15% efficiency and high reproducibility. Angew Chem Int Ed. 2021; 60(29): 15935-15943.
[73]

Fan Q, Fu H, Luo Z, et al. Near-infrared absorbing polymer acceptors enabled by selenophene-fused core and halogenated end-group for binary all-polymer solar cells with efficiency over 16%. Nano Energy. 2022; 92: 106718.
[74]

Fu H, Fan Q, Gao W, et al. 16.3% efficiency binary all-polymer solar cells enabled by a novel polymer acceptor with an asymmetrical selenophene-fused backbone. Sci China Chem. 2021; 65(2): 309-317.
[75]

Chen YN, Li M, Wang Y, et al. A fully non-fused ring acceptor with planar backbone and near-IR absorption for high performance polymer solar cells. Angew Chem Int Ed. 2020; 59(50): 22714-22720.
[76]

Liu Y, Ce Z, Hao D, et al. Enhancing the performance of organic solar cells by hierarchically supramolecular self-assembly of fused-ring electron acceptors. Chem Mater. 2018; 30(13): 4307-4312.
[77]

Zhang G, Chen X-K, Xiao J, et al. Delocalization of exciton and electron wavefunction in non-fullerene acceptor molecules enables efficient organic solar cells. Nat Commun. 2020; 11(1): 3943.
[78]

Fan B, Gao W, Wu X, et al. Importance of structural hinderance in performance-stability equilibrium of organic photovoltaics. Nat Commun. 2022; 13(1): 5946.
[79]

Chen H, Liang H, Guo Z, et al. Central unit fluorination of non-fullerene acceptors enables highly efficient organic solar cells with over 18% efficiency. Angew Chem Int Ed. 2022; 61(41): e202209580.
[80]

Liu K, Jiang Y, Ran G, Liu F, Zhang W, Zhu X. 19.7% efficiency binary organic solar cells achieved by selective core fluorination of nonfullerene electron acceptors. Joule. 2024; 8(3): 835-851.
[81]

Xu T, Luo Z, Ma R, et al. High-performance organic solar cells containing Pyrido[2, 3-b]quinoxaline-core-based small-molecule acceptors with optimized orbit overlap lengths and molecular packing. Angew Chem Int Ed. 2023; 62(30): e202304127.
[82]

Tan P, Liu L, Chen ZY, et al. Structure–property relationships of precisely chlorinated thiophene-substituted acceptors. Advd Funct Mater. 2021; 31(50): 2106524.
[83]

Chong K, Xu X, Meng H, et al. Realizing 19.05% efficiency polymer solar cells by progressively improving charge extraction and suppressing charge recombination. Adv Mater. 2022; 34(13): e2109516.
[84]

Gao W, Zhang M, Liu T, et al. Asymmetrical ladder-type donor-induced polar small molecule acceptor to promote fill factors approaching 77% for high-performance nonfullerene polymer solar cells. Adv Mater. 2018; 30(26): 1800052.
[85]

Li C, Xie Y, Fan B, Han G, Yi Y, Sun Y. A nonfullerene acceptor utilizing a novel asymmetric multifused-ring core unit for highly efficient organic solar cells. J Mater Chem C. 2018; 6(18): 4873-4877.
[86]

Fan B, Du X, Liu F, et al. Fine-tuning of the chemical structure of photoactive materials for highly efficient organic photovoltaics. Nat Energy. 2018; 3(12): 1051-1058.
[87]

Yao H, Wang J, Xu Y, Zhang S, Hou J. Recent progress in chlorinated organic photovoltaic materials. Acc Chem Res. 2020; 53(4): 822-832.
[88]

Fan B, Sun C, Jiang XF, et al. Improved morphology and efficiency of polymer solar cells by processing donor–acceptor copolymer additives. Adv Funct Mater. 2016; 26(35): 6479-6488.
[89]

Fan B, Li M, Zhang D, et al. Tailoring regioisomeric structures of π-conjugated polymers containing monofluorinated π-bridges for highly efficient polymer solar cells. ACS Energy Lett. 2020; 5(6): 2087-2094.
[90]

Fan Q, Zhu Q, Xu Z, et al. Chlorine substituted 2D-conjugated polymer for high-performance polymer solar cells with 13.1% efficiency via toluene processing. Nano Energy. 2018; 48: 413-420.
[91]

Luo Z, Ma R, Chen Z, et al. Altering the positions of chlorine and bromine substitution on the end group enables high-performance acceptor and efficient organic solar cells. Adv Energy Mater. 2020; 10(44): 2002649.
[92]

Chen H, Lai H, Chen Z, et al. 17.1%-efficient eco-compatible organic solar cells from a dissymmetric 3D network acceptor. Angew Chem Int Ed. 2021; 60(6): 3238-3246.
[93]

Fan B, Gao W, Wang Y, et al. Formation of vitrified solid solution enables simultaneously efficient and stable organic solar cells. ACS Energy Lett. 2021; 6(10): 3522-3529.
[94]

He C, Pan Y, Ouyang Y, et al. Manipulating the D:a interfacial energetics and intermolecular packing for 19.2% efficiency organic photovoltaics. Energy Environ Sci. 2022; 15(6): 2537-2544.
[95]

Fan B, Gao H, Jen AKY. Biaxially conjugated materials for organic solar cells. ACS Nano. 2024; 18(1): 136-154.
[96]

Chai G, Chang Y, Peng Z, et al. Enhanced hindrance from phenyl outer side chains on nonfullerene acceptor enables unprecedented simultaneous enhancement in organic solar cell performances with 16.7% efficiency. Nano Energy. 2020; 76: 105087.
[97]

Li T, Wu Q, Yao ZF, et al. Trialkylsilyl-thiophene-conjugated acceptor for efficient organic solar cells compatible with spin-coating and blade-coating technologies. Sci China Chem. 2024; 67: 1-10.
[98]

Kong X, Zhu C, Zhang J, et al. The effect of alkyl substitution position of thienyl outer side chains on photovoltaic performance of A–DA’D–A type acceptors. Energ Environ Sci. 2022; 15(5): 2011-2020.
[99]

Fan B, Zhong W, Gao W, et al. Understanding the role of removable solid additives: selective interaction contributes to vertical component distributions. Adv Mater. 2023; 35(32): e2302861.

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