Achieving and Understanding of Highly Efficient Ternary Organic Photovoltaics: From Morphology and Energy Loss to Working Mechanism

Abstract: design and device configuration innovation, the power conversion efficiencies (PCEs) of OPVs have been boosted rapidly in the recent few years. [6][7][8][9][10][11][12][13][14][15][16][17][18][19][20][21][22][23] Currently, the most advanced OPVs are based on Y-series non-fullerene acceptors (NFAs), for which a series of molecular structure optimizations, including alkyl chain tuning, [24,25] asymmetric terminals, [12,[26][27][28] and heteroatom exchanging, [29,30] are explored, and various ternary or tandem d… Show more

“…The CV characterization shows that the onset oxidation/reduction potentials (ϕ ox /ϕ red ) of Y6, Y6: ZCCF3, and ZCCF3 specimens are 1.31 V/-0.34 V, © 2023 Wiley-VCH GmbH 1.30 V/-0.43 V, and 1.29 V/-0.48 V, respectively, yielding their corresponding E HOMO /E LUMO of -5.65 eV/-4.00 eV, -5.64 eV/-3.91 eV, -5.63 eV/-3.86 eV (Figure 2b, Table 1). The results suggest that the structural torsion of ZCCF3 leads to a different electronic effect in both neat and dual acceptor blend, and its diazepine group can raise LUMO energy level to help boost the V OC output in OSCs, [43] consistent with the proposed molecular geometry aforementioned.…”

Diffusion‐Limited Accepter Alloy Enables Highly Efficient and Stable Organic Solar Cells

“…The CV characterization shows that the onset oxidation/reduction potentials (ϕ ox /ϕ red ) of Y6, Y6: ZCCF3, and ZCCF3 specimens are 1.31 V/-0.34 V, © 2023 Wiley-VCH GmbH 1.30 V/-0.43 V, and 1.29 V/-0.48 V, respectively, yielding their corresponding E HOMO /E LUMO of -5.65 eV/-4.00 eV, -5.64 eV/-3.91 eV, -5.63 eV/-3.86 eV (Figure 2b, Table 1). The results suggest that the structural torsion of ZCCF3 leads to a different electronic effect in both neat and dual acceptor blend, and its diazepine group can raise LUMO energy level to help boost the V OC output in OSCs, [43] consistent with the proposed molecular geometry aforementioned.…”

Diffusion‐Limited Accepter Alloy Enables Highly Efficient and Stable Organic Solar Cells

“…18,[52][53][54][55][56] These results strongly imply that the molecular structures of NFAs and their molecular packing behaviors in the solid state play critical roles in determining the E loss and the final device performance. In this regard, new structural optimization strategies for FREAs have been continuously explored to further reduce the E loss , 15,57 among which symmetry breaking has recently been proven as an effective strategy. Compared to the symmetric structure, asymmetric structural design can endow the resulting FREAs with a larger dipolar moment and an enhanced intermolecular binding energy, leading to intensified intermolecular interactions and increased packing order, both of which are desired for suppressing NRR loss.…”

Symmetry breaking: an efficient structure design of nonfullerene acceptors to reduce the energy loss in organic solar cells

“…[31][32][33] In addition, a multicomponent strategy introducing extra donor or acceptor components to binary systems is commonly used to improve the carrier dynamics and device parameters, especially in pursuing a higher V oc . [34][35][36][37][38][39][40][41] However, how the extra component combines with the host materials at the nanoscale level is not yet well understood, building barriers to acquiring design rules for successful multicomponent blends. 42 In summary, the field of nanoscale study on interfaces is still blank but is critical to the exploration of successful multicomponent systems with comprehensive carrier management, particularly with non-radiative recombination loss mitigation.…”

Refined molecular microstructure and optimized carrier management of multicomponent organic photovoltaics toward 19.3% certified efficiency