Xiaozhen Huang, Taiyu Wang, Wenjie Chen, Zhengye Wang, Zhiye Lin, Di Wang, Xiaofeng Li, Diwei Zhang, Shidong Cai, Xiafeng He, Jie Gao, Dong Wei, Hongfang Du, Youchao Wei, Yue Wang, Mingwei An, Yang Wang
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引用次数: 0
Abstract
Self-assembling molecules (SAMs) are widely used as interfacial layers to optimize the surface properties of nickel oxides (NiOx) in inverted perovskite solar cells (PSCs). However, less attention is paid to the effect of SAMs on the regulation of perovskite growth and energetics. Here, based on the donor-acceptor molecular backbone, an oligoether chain is introduced with different chain lengths to endow two novel SAMs, namely, EPA and MEPA, with good capability of bottom-up regulation of perovskite formation and energetics. Compared to the model SAM MPA, EPA and MEPA can render NiOx with better coverage and conductivity. Moreover, the oligoether chain-containing SAMs are able to assist the formation of perovskite film with ordered growth, high crystallization, and importantly well-matched energy level alignment at the top surface, especially for MEPA. Consequently, a remarkably high efficiency of 25.50% is realized for NiOx/MEPA-based PSCs along with good device stability, which can maintain 90% of the initial efficiency under ISOS-L-1 conditions over 1260 h.
自组装分子(sam)被广泛用作优化倒钙钛矿太阳能电池(PSCs)中氧化镍(NiOx)表面性能的界面层。然而,对SAMs对钙钛矿生长和能量学的调控作用的研究较少。本文基于供体-受体分子骨架,引入不同链长的低聚醚链,赋予EPA和MEPA两种新型sam具有良好的自下而上调节钙钛矿形成和能量学的能力。与SAM MPA模型相比,EPA和MEPA可以使NiOx具有更好的覆盖度和导电性。此外,含有低聚醚链的sam能够帮助形成钙钛矿薄膜,具有有序生长,高结晶和重要的顶部表面匹配良好的能级排列,特别是对于MEPA。因此,基于NiOx/MEPA的psc实现了25.50%的高效率,并且具有良好的器件稳定性,在iso - l -1条件下超过1260小时可以保持90%的初始效率。
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