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Surface-redox sodium-ion storage in anatase titanium oxide

Author

Listed:
  • Qiulong Wei

    (Xiamen University
    Innovation Laboratory for Sciences and Technologies of Energy Materials of Fujian Province (IKKEM))

  • Xiaoqing Chang

    (Xiamen University)

  • Danielle Butts

    (University of California Los Angeles)

  • Ryan DeBlock

    (University of California Los Angeles)

  • Kun Lan

    (Fudan University
    Inner Mongolia University)

  • Junbin Li

    (Xiamen University)

  • Dongliang Chao

    (Fudan University)

  • Dong-Liang Peng

    (Xiamen University
    Innovation Laboratory for Sciences and Technologies of Energy Materials of Fujian Province (IKKEM))

  • Bruce Dunn

    (University of California Los Angeles)

Abstract

Sodium-ion storage technologies are promising candidates for large-scale grid systems due to the abundance and low cost of sodium. However, compared to well-understood lithium-ion storage mechanisms, sodium-ion storage remains relatively unexplored. Herein, we systematically determine the sodium-ion storage properties of anatase titanium dioxide (TiO2(A)). During the initial sodiation process, a thin surface layer (~3 to 5 nm) of crystalline TiO2(A) becomes amorphous but still undergoes Ti4+/Ti3+ redox reactions. A model explaining the role of the amorphous layer and the dependence of the specific capacity on the size of TiO2(A) nanoparticles is proposed. Amorphous nanoparticles of ~10 nm seem to be optimum in terms of achieving high specific capacity, on the order of 200 mAh g−1, at high charge/discharge rates. Kinetic studies of TiO2(A) nanoparticles indicate that sodium-ion storage is due to a surface-redox mechanism that is not dependent on nanoparticle size in contrast to the lithiation of TiO2(A) which is a diffusion-limited intercalation process. The surface-redox properties of TiO2(A) result in excellent rate capability, cycling stability and low overpotentials. Moreover, tailoring the surface-redox mechanism enables thick electrodes of TiO2(A) to retain high rate properties, and represents a promising direction for high-power sodium-ion storage.

Suggested Citation

  • Qiulong Wei & Xiaoqing Chang & Danielle Butts & Ryan DeBlock & Kun Lan & Junbin Li & Dongliang Chao & Dong-Liang Peng & Bruce Dunn, 2023. "Surface-redox sodium-ion storage in anatase titanium oxide," Nature Communications, Nature, vol. 14(1), pages 1-9, December.
    • Handle: RePEc:nat:natcom:v:14:y:2023:i:1:d:10.1038_s41467-022-35617-3
    DOI: 10.1038/s41467-022-35617-3
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    References listed on IDEAS

    as
    1. Maria R. Lukatskaya & Bruce Dunn & Yury Gogotsi, 2016. "Multidimensional materials and device architectures for future hybrid energy storage," Nature Communications, Nature, vol. 7(1), pages 1-13, November.
    2. Simon Fleischmann & Yuan Zhang & Xuepeng Wang & Peter T. Cummings & Jianzhong Wu & Patrice Simon & Yury Gogotsi & Volker Presser & Veronica Augustyn, 2022. "Continuous transition from double-layer to Faradaic charge storage in confined electrolytes," Nature Energy, Nature, vol. 7(3), pages 222-228, March.
    3. Kaikai Li & Jun Zhang & Dongmei Lin & Da-Wei Wang & Baohua Li & Wei Lv & Sheng Sun & Yan-Bing He & Feiyu Kang & Quan-Hong Yang & Limin Zhou & Tong-Yi Zhang, 2019. "Evolution of the electrochemical interface in sodium ion batteries with ether electrolytes," Nature Communications, Nature, vol. 10(1), pages 1-10, December.
    4. Kaikai Li & Jun Zhang & Dongmei Lin & Da-Wei Wang & Baohua Li & Wei Lv & Sheng Sun & Yan-Bing He & Feiyu Kang & Quan-Hong Yang & Limin Zhou & Tong-Yi Zhang, 2019. "Author Correction: Evolution of the electrochemical interface in sodium ion batteries with ether electrolytes," Nature Communications, Nature, vol. 10(1), pages 1-1, December.
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