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Enriching conductive capping by alkaline treatment of perovskite quantum dots towards certified 18.3%-efficient solar cells

Author

Listed:
  • Donglin Jia

    (North China Electric Power University)

  • Jiaxin Li

    (North China Electric Power University)

  • Kefan Zhu

    (North China Electric Power University)

  • Hengwei Qiu

    (North China Electric Power University)

  • Liang Li

    (North China Electric Power University)

  • Xing Zhao

    (North China Electric Power University)

  • Zhineng Lan

    (North China Electric Power University)

  • Huilin Yan

    (North China Electric Power University)

  • Fu Yang

    (North China Electric Power University)

  • Peng Cui

    (North China Electric Power University)

  • Xin Sun

    (North China Electric Power University)

  • Haifang Li

    (North China Electric Power University)

  • Pengkun Zhu

    (North China Electric Power University)

  • Shaofeng Liu

    (Haidian)

  • Meicheng Li

    (North China Electric Power University)

Abstract

Perovskite quantum dots (PQD) hold great promise for next-generation photovoltaics. However, neat ester antisolvents hydrolyze inefficiently into target ligands under ambient conditions, compromising the formation of integral conductive capping on PQD surfaces. Herein, we construct alkaline environments, which facilitate the rapid substitution of pristine insulating oleate ligands with up to twice the conventional amount of hydrolyzed conductive counterparts. Theoretical calculations reveal that this environment renders ester hydrolysis thermodynamically spontaneous and lowers reaction activation energy by approximately 9-fold. Through tailoring potassium hydroxide coupled with methyl benzoate antisolvent for interlayer rinsing of PQD solids, the assembled light-absorbing layers exhibit fewer trap-states, homogeneous orientations, and minimal particle agglomerations. Consequently, the fabricated solar cells (0.036 cm2) achieve a certified efficiency of 18.3%, the highest value among published PQD solar cell reports, alongside a steady-state efficiency of 17.85% and an average efficiency of 17.68% over 20 devices. Moreover, the alkaline treatment is broadly compatible with diverse solid-state treatments and PQD compositions, demonstrating universality in modulating PQD surface chemistry.

Suggested Citation

  • Donglin Jia & Jiaxin Li & Kefan Zhu & Hengwei Qiu & Liang Li & Xing Zhao & Zhineng Lan & Huilin Yan & Fu Yang & Peng Cui & Xin Sun & Haifang Li & Pengkun Zhu & Shaofeng Liu & Meicheng Li, 2025. "Enriching conductive capping by alkaline treatment of perovskite quantum dots towards certified 18.3%-efficient solar cells," Nature Communications, Nature, vol. 16(1), pages 1-14, December.
    • Handle: RePEc:nat:natcom:v:16:y:2025:i:1:d:10.1038_s41467-025-63618-5
    DOI: 10.1038/s41467-025-63618-5
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