Organic polymeric and small molecular electron acceptors for organic solar cells

In organic solar cells (OSCs), the electron donor (D) and electron acceptor (A) blended active layer is the most crucial component for governing the power conversion efficiency (PCE). Various efficient donor materials with wide structural variations have been developed to couple with high-electron m...

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Published in:Materials science & engineering. R, Reports : a review journal Reports : a review journal, 2018-02, Vol.124, p.1-57
Main Authors: A., Venkateswararao, Liu, Shun-Wei, Wong, Ken-Tsung
Format: Article
Language:English
Subjects:
Absorption
Bulk heterojunction
Charge transport
Diimide
Dimers
Donor materials
Electrochemical analysis
Electron affinity
Electron mobility
Electrons
Energy conversion efficiency
Energy levels
Flexibility
Fullerenes
Indacenodithiophene
Inspection
Mathematical morphology
Molecular chains
Non-fullerene acceptor
Optical properties
Optimization
Organic chemistry
Organic solar cell
Perylene diimide
Photovoltaic cells
Physical properties
Polymeric acceptor
Polymers
Small molecule acceptor
Solar cells
Structural engineering
Trimers
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Summary:In organic solar cells (OSCs), the electron donor (D) and electron acceptor (A) blended active layer is the most crucial component for governing the power conversion efficiency (PCE). Various efficient donor materials with wide structural variations have been developed to couple with high-electron mobility fullerene-based acceptors, giving PCEs beyond 12%. However, fullerene-embedded OSCs encounter great challenges of low flexibility for structural modifications, poor absorption and blend morphological stability. The demand for alternative acceptors drives current OSC research towards non-fullerene acceptors (NFAs). Tailor-made NFAs of polymer or small molecule (SM) can typically exhibit tunable optical and electrochemical properties, high solubility, air stability, and favorable intermolecular interactions leading to compact packing and good nano-phase segregation in the active blend. In this review, we systematically depict the effects of molecular structures on the physical properties and device performances. The promising/most popular cores and general molecular design strategies of NFAs are outlined. The polymeric and SM NFAs were classified into several sub-groups based on their structural features, and in every sub-group, the structural evolution, current status, the champion case as well as the future challenges were highlighted and discussed. For polymeric NFAs, naphtalene diimide (NDI) and perylene diimide (PDI) are most promising and widely explored due to their easy synthesis, high electron affinity and mobility, leading to promising PCE when NDI and PDI units are conjugated with various electron-rich/deficient aromatics. Various electron-deficient core-based polymeric NFAs were also employed. Aromatic diimides (NDI and PDI) were also widely employed as the central core or terminal unit for SM NFAs. In particular, PDI was interested in electron deficient core, and their monomers, dimers, and trimers gave various degrees of success. PDI trimeric NFA showed superior PCE (∼9.3%) because of its twisted 3D or fused geometry capable of interlocking the polymer donor allows optimum molecular packing, morphology and, therefore, efficient charge separation and transport. The excellent photochemical stability, strong absorption and synthetic flexibility of diketopyrrolopyrrole (DPP) produced promising SM NFAs. The rigid and co-planar indacenodithiophene (IDT) cores bearing various electron-deficient terminal groups were extensively explored, and the stru
ISSN:0927-796X
1879-212X
DOI:10.1016/j.mser.2018.01.001