Efficient carrier transport via dual-function interfacial engineering using cesium iodide for high-performance perovskite solar cells based on NiOx hole transporting materials

作     者：Taotao Hu Fu Zhang Hua Yu Meng Zhang Yue Yu Wenfeng Zhang Rui Liu Liuwen Tian Zhu Ma Taotao Hu;Fu Zhang;Hua Yu;Meng Zhang;Yue Yu;Wenfeng Zhang;Rui Liu;Liuwen Tian;Zhu Ma

作者机构：Institute of PhotovoltaicsSouthwest Petroleum UniversityChengdu610500China 

出 版 物：《Nano Research》 (纳米研究（英文版）)

年 卷 期：2021年第14卷第11期

页      面：3864-3872页

核心收录：

学科分类：081704[工学-应用化学] 07[理学] 08[工学] 0817[工学-化学工程与技术] 070303[理学-有机化学] 0703[理学-化学] 

基　　金：This research was supported by the Sichuan Science and Technology Program(No.2021YFH0090) Scientific Research Start-Up Project of Southwest Petroleum University,China(No.X151528) The authors are grateful to the colleagues for their assistance 

主　　题：perovskite solar cells(PSCs) NiO_(x) surface passivation engineering cesium iodide high fill factor 

摘      要：As a famous hole transporting material, nickle oxide (NiOx) has drawn enormous attention due to its low cost and superior stability. However, the relatively low conductivity and high-density surface trap states of NiOx severely limit device performance in solar cell applications. Interfacial engineering is an efficient approach to achieve remarkable hole-transporting performance by surface passivation. Herein, the efficient NiOx hole transport layer was prepared by surface passivation engineering strategy via facile solution processes with cesium iodide (CsI). It is demonstrated that CsI plays a super-effective dual-function role in inverted solar cell device: On one hand, the presence of CsI hugely passivates the surface trap states at the NiOx/perovskite interface along with obviously improved conductivity by the incorporated Cs^(+);on the other hand, the ions immigration is significantly suppressed by the presence of I ion for high-quality perovskite films, resulting in a stable contact interface. The ameliorative interface leads to largely reduced carrier non-radiative recombination, attributing to boosted carrier extraction efficiency. As a result, decent power conversion efficiency (PCE) of 18.48% with a noticeable fill factor (FF) beyond 80% was achieved. This facile and efficient surface engineering approach with dual-function shows excellent potential for the design of high-performance functional interfacial modification layer to achieve high-performance solar cells.