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D-orbital Reconstruction Achieves Low Charge Overpotential in Li-oxygen Batteries

Author

Listed:
  • Yin Zhou

    (83 Tat Chee Avenue)

  • Kun Yin

    (Ludong University)

  • Yingying Huang

    (83 Tat Chee Avenue)

  • Jiapei Li

    (83 Tat Chee Avenue)

  • Anquan Zhu

    (83 Tat Chee Avenue)

  • Dewu Lin

    (83 Tat Chee Avenue)

  • Guoqiang Gan

    (83 Tat Chee Avenue)

  • Jianfang Zhang

    (83 Tat Chee Avenue)

  • Kai Liu

    (83 Tat Chee Avenue)

  • Tian Zhang

    (83 Tat Chee Avenue)

  • Kunlun Liu

    (83 Tat Chee Avenue)

  • Chuhao Luan

    (83 Tat Chee Avenue)

  • Huawei Yang

    (Ludong University)

  • Hou Chen

    (Ludong University)

  • Shaojun Guo

    (Peking University)

  • Wenjun Zhang

    (83 Tat Chee Avenue)

  • Guo Hong

    (83 Tat Chee Avenue
    City University of Hong Kong)

Abstract

Charge overpotential for oxygen evolution reaction is a crucial parameter for the energy conversion efficiency of lithium-oxygen (Li-O2) batteries. So far, the realization of low charge overpotential via catalyst design is a grand challenge in this field, which usually exceeds 0.25 V. Herein, we report an orbital reconstruction strategy to significantly decrease the charge overpotential to the low 0.11 V by employing PdCo nanosheet catalyst under a low-loading mass (0.3 mg/cm2) and capacity (0.3 mAh/cm2). Experimental and theoretical calculations demonstrate that the precise d-d orbital coupling (dxz-dxz, dyz-dyz and dz2-dz2) between the low-electronegativity Co and Pd leads to the reconstruction of Pd 4 d orbitals in PdCo nanosheets, thereby resulting in a downward shift of all the three active Pd 4 d orbitals (dz2, dxz and dyz) relative to that of Pd nanosheets. Furthermore, the highest energy level of the Pd 4dz2 orbital in PdCo is lower than the lowest energy levels of the Pd 4dxz and 4dyz orbitals in pure Pd, significantly decreasing the charge activation energy and achieving a highest energy conversion efficiency of 91%. This finding provides the orbital-level tuning into rational design of highly efficient electrocatalysts for Li-O2 batteries.

Suggested Citation

  • Yin Zhou & Kun Yin & Yingying Huang & Jiapei Li & Anquan Zhu & Dewu Lin & Guoqiang Gan & Jianfang Zhang & Kai Liu & Tian Zhang & Kunlun Liu & Chuhao Luan & Huawei Yang & Hou Chen & Shaojun Guo & Wenju, 2025. "D-orbital Reconstruction Achieves Low Charge Overpotential in Li-oxygen Batteries," Nature Communications, Nature, vol. 16(1), pages 1-9, December.
    • Handle: RePEc:nat:natcom:v:16:y:2025:i:1:d:10.1038_s41467-025-58640-6
    DOI: 10.1038/s41467-025-58640-6
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    References listed on IDEAS

    as
    1. Mohammad Asadi & Baharak Sayahpour & Pedram Abbasi & Anh T. Ngo & Klas Karis & Jacob R. Jokisaari & Cong Liu & Badri Narayanan & Marc Gerard & Poya Yasaei & Xuan Hu & Arijita Mukherjee & Kah Chun Lau , 2018. "A lithium–oxygen battery with a long cycle life in an air-like atmosphere," Nature, Nature, vol. 555(7697), pages 502-506, March.
    2. Peng Wang & Yingying Ren & Rutao Wang & Peng Zhang & Mingjie Ding & Caixia Li & Danyang Zhao & Zhao Qian & Zhiwei Zhang & Luyuan Zhang & Longwei Yin, 2020. "Atomically dispersed cobalt catalyst anchored on nitrogen-doped carbon nanosheets for lithium-oxygen batteries," Nature Communications, Nature, vol. 11(1), pages 1-11, December.
    3. Jun Lu & Yun Jung Lee & Xiangyi Luo & Kah Chun Lau & Mohammad Asadi & Hsien-Hau Wang & Scott Brombosz & Jianguo Wen & Dengyun Zhai & Zonghai Chen & Dean J. Miller & Yo Sub Jeong & Jin-Bum Park & Zhiga, 2016. "A lithium–oxygen battery based on lithium superoxide," Nature, Nature, vol. 529(7586), pages 377-382, January.
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    5. Liangzhu Zhang & Zixuan Yang & Shun Feng & Zhuobin Guo & Qingchao Jia & Huidan Zeng & Yajun Ding & Pratteek Das & Zhihong Bi & Jiaxin Ma & Yunqi Fu & Sen Wang & Jinxing Mi & Shuanghao Zheng & Mingrun , 2024. "Metal telluride nanosheets by scalable solid lithiation and exfoliation," Nature, Nature, vol. 628(8007), pages 313-319, April.
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