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Transition metal-catalysed molecular n-doping of organic semiconductors

Author

Listed:
  • Han Guo

    (Southern University of Science and Technology (SUSTech))

  • Chi-Yuan Yang

    (Linköping University)

  • Xianhe Zhang

    (Southern University of Science and Technology (SUSTech))

  • Alessandro Motta

    (Università di Roma “La Sapienza” and INSTM, UdR Roma)

  • Kui Feng

    (Southern University of Science and Technology (SUSTech))

  • Yu Xia

    (Flexterra Corporation)

  • Yongqiang Shi

    (Southern University of Science and Technology (SUSTech))

  • Ziang Wu

    (Korea University)

  • Kun Yang

    (Southern University of Science and Technology (SUSTech))

  • Jianhua Chen

    (Southern University of Science and Technology (SUSTech))

  • Qiaogan Liao

    (Southern University of Science and Technology (SUSTech))

  • Yumin Tang

    (Southern University of Science and Technology (SUSTech))

  • Huiliang Sun

    (Southern University of Science and Technology (SUSTech))

  • Han Young Woo

    (Korea University)

  • Simone Fabiano

    (Linköping University)

  • Antonio Facchetti

    (Linköping University
    Flexterra Corporation
    Northwestern University)

  • Xugang Guo

    (Southern University of Science and Technology (SUSTech))

Abstract

Chemical doping is a key process for investigating charge transport in organic semiconductors and improving certain (opto)electronic devices1–9. N(electron)-doping is fundamentally more challenging than p(hole)-doping and typically achieves a very low doping efficiency (η) of less than 10%1,10. An efficient molecular n-dopant should simultaneously exhibit a high reducing power and air stability for broad applicability1,5,6,9,11, which is very challenging. Here we show a general concept of catalysed n-doping of organic semiconductors using air-stable precursor-type molecular dopants. Incorporation of a transition metal (for example, Pt, Au, Pd) as vapour-deposited nanoparticles or solution-processable organometallic complexes (for example, Pd2(dba)3) catalyses the reaction, as assessed by experimental and theoretical evidence, enabling greatly increased η in a much shorter doping time and high electrical conductivities (above 100 S cm−1; ref. 12). This methodology has technological implications for realizing improved semiconductor devices and offers a broad exploration space of ternary systems comprising catalysts, molecular dopants and semiconductors, thus opening new opportunities in n-doping research and applications12, 13.

Suggested Citation

  • Han Guo & Chi-Yuan Yang & Xianhe Zhang & Alessandro Motta & Kui Feng & Yu Xia & Yongqiang Shi & Ziang Wu & Kun Yang & Jianhua Chen & Qiaogan Liao & Yumin Tang & Huiliang Sun & Han Young Woo & Simone F, 2021. "Transition metal-catalysed molecular n-doping of organic semiconductors," Nature, Nature, vol. 599(7883), pages 67-73, November.
    • Handle: RePEc:nat:nature:v:599:y:2021:i:7883:d:10.1038_s41586-021-03942-0
    DOI: 10.1038/s41586-021-03942-0
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    Cited by:

    1. Yu Pu & Haijun Su & Congcong Liu & Min Guo & Lin Liu & Hengzhi Fu, 2023. "A Review on Buried Interface of Perovskite Solar Cells," Energies, MDPI, vol. 16(13), pages 1-30, June.
    2. Miao Xiong & Xin-Yu Deng & Shuang-Yan Tian & Kai-Kai Liu & Yu-Hui Fang & Juan-Rong Wang & Yunfei Wang & Guangchao Liu & Jupeng Chen & Diego Rosas Villalva & Derya Baran & Xiaodan Gu & Ting Lei, 2024. "Counterion docking: a general approach to reducing energetic disorder in doped polymeric semiconductors," Nature Communications, Nature, vol. 15(1), pages 1-10, December.

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