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对非富勒烯小分子受体的能级进行精细调控,以在有机太阳能电池中实现超过 12%的高短路电流和功率转换效率。

Fine-Tuning the Energy Levels of a Nonfullerene Small-Molecule Acceptor to Achieve a High Short-Circuit Current and a Power Conversion Efficiency over 12% in Organic Solar Cells.

机构信息

State Key Laboratory and Institute of Elemento-Organic Chemistry, The Centre of Nanoscale Science and Technology and Key Laboratory of Functional Polymer Materials, College of Chemistry, Nankai University, Tianjin, 300071, China.

Department of Chemistry, Imperial College London, London, SW7 2AZ, UK.

出版信息

Adv Mater. 2018 Jan;30(3). doi: 10.1002/adma.201704904. Epub 2017 Dec 4.

DOI:10.1002/adma.201704904
PMID:29205535
Abstract

Organic solar cell optimization requires careful balancing of current-voltage output of the materials system. Here, such optimization using ultrafast spectroscopy as a tool to optimize the material bandgap without altering ultrafast photophysics is reported. A new acceptor-donor-acceptor (A-D-A)-type small-molecule acceptor NCBDT is designed by modification of the D and A units of NFBDT. Compared to NFBDT, NCBDT exhibits upshifted highest occupied molecular orbital (HOMO) energy level mainly due to the additional octyl on the D unit and downshifted lowest unoccupied molecular orbital (LUMO) energy level due to the fluorination of A units. NCBDT has a low optical bandgap of 1.45 eV which extends the absorption range toward near-IR region, down to ≈860 nm. However, the 60 meV lowered LUMO level of NCBDT hardly changes the V level, and the elevation of the NCBDT HOMO does not have a substantial influence on the photophysics of the materials. Thus, for both NCBDT- and NFBDT-based systems, an unusually slow (≈400 ps) but ultimately efficient charge generation mediated by interfacial charge-pair states is observed, followed by effective charge extraction. As a result, the PBDB-T:NCBDT devices demonstrate an impressive power conversion efficiency over 12%-among the best for solution-processed organic solar cells.

摘要

有机太阳能电池的优化需要仔细平衡材料体系的电流-电压输出。在这里,我们报告了一种使用超快光谱学作为工具来优化材料带隙而不改变超快光物理的优化方法。通过对 NFBDT 的 D 和 A 单元进行修饰,设计了一种新型的给体-受体-给体(A-D-A)型小分子受体 NCBDT。与 NFBDT 相比,NCBDT 的最高占据分子轨道(HOMO)能级上移,主要是由于 D 单元上增加了辛基,而最低未占据分子轨道(LUMO)能级下移是由于 A 单元的氟化。NCBDT 的光学带隙低至 1.45 eV,这将吸收范围扩展到近红外区域,截止波长约为 860nm。然而,NCBDT 的 LUMO 能级降低 60 meV 几乎不会改变 V 能级,而 NCBDT 的 HOMO 升高对材料的光物理影响不大。因此,对于基于 NCBDT 和 NFBDT 的体系,观察到一种异常缓慢(≈400 ps)但最终有效的通过界面电荷对态介导的电荷产生,然后是有效的电荷提取。结果,PBDB-T:NCBDT 器件的功率转换效率超过 12%,在溶液处理的有机太阳能电池中属于最佳之列。

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