Interdisciplinary Materials (Apr 2022)

Subtle side chain modification of triphenylamine‐based polymer hole‐transport layer materials produces efficient and stable inverted perovskite solar cells

  • Yue‐Min Xie,
  • Qin Yao,
  • Qifan Xue,
  • Zixin Zeng,
  • Tianqi Niu,
  • Yingzhi Zhou,
  • Ming‐Peng Zhuo,
  • Sai‐Wing Tsang,
  • Hin‐Lap Yip,
  • Yong Cao

DOI
https://doi.org/10.1002/idm2.12023
Journal volume & issue
Vol. 1, no. 2
pp. 281 – 293

Abstract

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Abstract Polymer hole‐transport layers (HTLs) are critical components of inverted perovskite solar cells (IPVSCs). Triphenylamine derivatives PTAA (poly[bis(4‐phenyl)(2,4,6‐trimethylphenyl)amine]) and Poly‐TPD (poly[N,N′‐bis(4‐butylphenyl)‐N,N′‐bis(phenyl)benzidine]) have been widely adopted as hole‐transport materials due to their perovskite passivation effects and suitable energy levels. However, the passivation mechanism (i.e., the functional group responsible for perovskite passivation) of triphenylamine derivative polymers remains unclear, hindering the development and application of this polymer type. Here, we develop a novel Poly‐TPD derivative, S‐Poly‐TPD, by replacing the n‐butyl functional group of Poly‐TPD with an isobutyl group to explore the influence of alkyl groups on HTL performance and top‐deposited perovskite properties. Compared with Poly‐TPD, the increased CH3‐terminal unit density and the decreased spatial distance between the –CH–CH3 and –CH2–CH3 units and the benzene ring in S‐Poly‐TPD not only enhanced the hole‐transport ability but also improved the perovskite passivation effect, revealing for the first time the role of the alkyl groups in perovskite passivation. As a result, the S‐Poly‐TPD‐based IPVSCs demonstrated high power‐conversion efficiencies of 15.1% and 21.3% in wide‐bandgap [MAPbI2Br(SCN)0.12] and normal‐bandgap [(FAPbI3)0.92(MAPbBr3)0.08] devices, respectively.

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