Nature Communications (Jun 2024)

Intrinsically stretchable organic photovoltaics by redistributing strain to PEDOT:PSS with enhanced stretchability and interfacial adhesion

  • Jiachen Wang,
  • Yuto Ochiai,
  • Niannian Wu,
  • Kiyohiro Adachi,
  • Daishi Inoue,
  • Daisuke Hashizume,
  • Desheng Kong,
  • Naoji Matsuhisa,
  • Tomoyuki Yokota,
  • Qiang Wu,
  • Wei Ma,
  • Lulu Sun,
  • Sixing Xiong,
  • Baocai Du,
  • Wenqing Wang,
  • Chih-Jen Shih,
  • Keisuke Tajima,
  • Takuzo Aida,
  • Kenjiro Fukuda,
  • Takao Someya

DOI
https://doi.org/10.1038/s41467-024-49352-4
Journal volume & issue
Vol. 15, no. 1
pp. 1 – 12

Abstract

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Abstract Intrinsically stretchable organic photovoltaics have emerged as a prominent candidate for the next-generation wearable power generators regarding their structural design flexibility, omnidirectional stretchability, and in-plane deformability. However, formulating strategies to fabricate intrinsically stretchable organic photovoltaics that exhibit mechanical robustness under both repetitive strain cycles and high tensile strains remains challenging. Herein, we demonstrate high-performance intrinsically stretchable organic photovoltaics with an initial power conversion efficiency of 14.2%, exceptional stretchability (80% of the initial power conversion efficiency maintained at 52% tensile strain), and cyclic mechanical durability (95% of the initial power conversion efficiency retained after 100 strain cycles at 10%). The stretchability is primarily realised by delocalising and redistributing the strain in the active layer to a highly stretchable PEDOT:PSS electrode developed with a straightforward incorporation of ION E, which simultaneously enhances the stretchability of PEDOT:PSS itself and meanwhile reinforces the interfacial adhesion with the polyurethane substrate. Both enhancements are pivotal factors ensuring the excellent mechanical durability of the PEDOT:PSS electrode, which further effectively delays the crack initiation and propagation in the top active layer, and enables the limited performance degradation under high tensile strains and repetitive strain cycles.