<p>The commercialization of all-perovskite tandem solar modules is hindered by the reliance on the conventional gold-based tunnel recombination junction<sup><CitationRef CitationID="CR1">1</CitationRef>,<CitationRef CitationID="CR2">2</CitationRef></sup>. Specifically, this tunnel recombination junction introduces substantial near-infrared parasitic absorption<sup><CitationRef CitationID="CR3">3</CitationRef></sup> and suffers from interfacial instability<sup><CitationRef CitationID="CR4">4</CitationRef></sup>, limiting both photocurrent generation and operational durability. Here, we develop a solution-processed interconnecting layer based on surface-engineered indium oxide nanocrystals featuring high optical transparency, in which controlled nanocrystal morphology and tailored ligand chemistry enable smooth interfacial contact and favourable energy-level alignment. We introduce a phosphonic acid additive into the lead–tin perovskite precursor, which synergistically improves the electronic contact with the indium oxide recombination layer, thereby enhancing hole extraction. Moreover, the additive regulates perovskite crystallization to mitigate residual strain during film formation, ensuring high-quality large-area deposits. This coordinated interfacial and crystallization engineering strategy simultaneously enhances carrier recombination efficiency at the interconnection layer, improves carrier extraction and promotes large-area film uniformity in all-perovskite tandems. As a result, a 65-cm<sup>2</sup> all-perovskite tandem solar module achieves a certified power conversion efficiency of 26.2% (ref. <sup><CitationRef CitationID="CR5">5</CitationRef></sup>), with an open-circuit voltage of 2.182 V, a fill factor of 77.4% and a short-circuit current density of 15.6 mA cm<sup>−2</sup> in terms of averaged subcell performance, measured by the Japan Electrical Safety and Environment Technology Laboratories. This marks a notable advance towards scalable perovskite tandem photovoltaics.</p>

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Nanocrystal-tailored recombination for all-perovskite tandem solar modules

  • Ke Xiao,
  • Hongfei Sun,
  • Xinke Kong,
  • Han Gao,
  • Jing Lou,
  • Xingze Chen,
  • Zimo Hu,
  • Dongdong Xu,
  • Renxing Lin,
  • Runnan Liu,
  • Siyu Xia,
  • Jin Xie,
  • Ye Liu,
  • Xin Luo,
  • Fengjia Fan,
  • Changqi Ma,
  • Chao Chang,
  • Yuanyuan Wang,
  • Hairen Tan

摘要

The commercialization of all-perovskite tandem solar modules is hindered by the reliance on the conventional gold-based tunnel recombination junction1,2. Specifically, this tunnel recombination junction introduces substantial near-infrared parasitic absorption3 and suffers from interfacial instability4, limiting both photocurrent generation and operational durability. Here, we develop a solution-processed interconnecting layer based on surface-engineered indium oxide nanocrystals featuring high optical transparency, in which controlled nanocrystal morphology and tailored ligand chemistry enable smooth interfacial contact and favourable energy-level alignment. We introduce a phosphonic acid additive into the lead–tin perovskite precursor, which synergistically improves the electronic contact with the indium oxide recombination layer, thereby enhancing hole extraction. Moreover, the additive regulates perovskite crystallization to mitigate residual strain during film formation, ensuring high-quality large-area deposits. This coordinated interfacial and crystallization engineering strategy simultaneously enhances carrier recombination efficiency at the interconnection layer, improves carrier extraction and promotes large-area film uniformity in all-perovskite tandems. As a result, a 65-cm2 all-perovskite tandem solar module achieves a certified power conversion efficiency of 26.2% (ref. 5), with an open-circuit voltage of 2.182 V, a fill factor of 77.4% and a short-circuit current density of 15.6 mA cm−2 in terms of averaged subcell performance, measured by the Japan Electrical Safety and Environment Technology Laboratories. This marks a notable advance towards scalable perovskite tandem photovoltaics.