Novel hole transporting materials based on cyclopentadithiophene for perovskite solar cells

IF 3.261
Ying-Sheng Lin , Nai-Hwa Chen , Yi-Ru Chen , Kollimalayan Kalidass , Hsiu-Yao Cheng , Parthasarathy Venkatakrishnan , Tahsin J. Chow , Yuan Jay Chang
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引用次数: 3

Abstract

We have demonstrated three LY-HTMs for perovskite solar cells in this report. These LY-HTMs embed cyclopentadithiophene (CPT) core that incorporates 2∼4 triphenylamine electron donor units. Designing LY-HTMs with Lewis-basic property of carbonyl or imine, can effectively passivate the defects of insufficiently coordinated Pb2+ in the perovskite layer. The LY-HTMs have good thermal stability and enhanced intermolecular interaction, thereby dense packing, due to the sulfur-sulfur interaction in the dithiophene structure. Moreover, the sulfur-sulfur interaction achieves a deeper HOMO energy level that can be well-matched to perovskite solar cells (PSCs). It also improves the charge mobility to enhance Voc and Jsc values. The best performance using LY-1 as a HTM in PSCs exhibited a Jsc of 23.1 mA∙cm−2, a Voc of 1.06 V, and a fill factor of 0.78, corresponding to an overall conversion efficiency of 19.12% (the control device of spiro-OMeTAD, 17.69%). In addition, the PCEs of the LY-1 PSC devices underwent decays of only 90% and 74.8% of their original values after 10 and 30 days, respectively, under an Ar atmosphere.

Abstract Image

基于环戊二噻吩的钙钛矿太阳能电池新型空穴传输材料
在本报告中,我们展示了三种钙钛矿太阳能电池的LY-HTMs。这些LY-HTMs嵌入环戊二噻吩(CPT)核心,其中包含2 ~ 4个三苯胺电子给体单元。设计具有羰基或亚胺刘易斯碱性质的LY-HTMs,可以有效钝化钙钛矿层中Pb2+配位不足的缺陷。由于二噻吩结构中的硫-硫相互作用,LY-HTMs具有良好的热稳定性和增强的分子间相互作用,从而致密堆积。此外,硫-硫相互作用实现了更深的HOMO能级,可以很好地匹配钙钛矿太阳能电池(PSCs)。它还提高了电荷迁移率,提高了Voc和Jsc值。使用LY-1作为HTM在psc中的最佳性能表现为Jsc为23.1 mA∙cm−2,Voc为1.06 V,填充因子为0.78,相应的整体转换效率为19.12% (spiro-OMeTAD的控制装置为17.69%)。此外,LY-1 PSC器件在氩气环境下10天和30天后,pce分别衰减了原始值的90%和74.8%。
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