Journal article
Authors list: Karger, Leonhard; Korneychuk, Svetlana; van den Bergh, Wessel; Dreyer, Sören L; Zhang, Ruizhuo; Kondrakov, Aleksandr; Janek, Jürgen; Brezesinski, Torsten
Publication year: 2023
Pages: 1497-1512
Journal: Chemistry of Materials
Volume number: 36
Issue number: 3
ISSN: 0897-4756
eISSN: 1520-5002
DOI Link: https://doi.org/10.1021/acs.chemmater.3c02727
Publisher: American Chemical Society
Abstract:
Layered oxide cathode materials, such as LiNiaCobMncO2 or LiNiaCobAlcO2, are sought after mainly because of their high theoretical specific capacity. Especially those with a high nickel content are being pursued to increase capacity and lower costs. In these materials, substitutional defects are a common feature and are typically associated with poor overall quality. Herein, we employ a sodium-to-lithium ion exchange to produce LiNiO2 (LNO) without such characteristic defects. Three different methods are used to tailor the primary particle (grain) size over a broad range, and each material is subjected to electrochemical testing. By analyzing the initial charge/discharge profiles, we separate kinetic hindrance and structural degradation as two independent contributions to the first-cycle capacity loss. We find that the Ni-Li(center dot) point defects stabilize LNO at high potentials and help mitigate material degradation while leading to incomplete discharge. The kinetic hindrance at the end of discharge vanishes upon their removal, but the degradation at high states of charge becomes more pronounced. We examine the cause of material degradation and corroborate the results by artificially introducing pillaring Mg2+ ions through a novel dual-ion exchange as a model system for nickel substitutional defects. This methodology may be exploited to identify an optimal concentration of pillar ions, especially in a range of defect densities that are inaccessible by conventional solid-state synthesis.
Citation Styles
Harvard Citation style: Karger, L., Korneychuk, S., van den Bergh, W., Dreyer, S., Zhang, R., Kondrakov, A., et al. (2023) Seesaw Effect of Substitutional Point Defects on the Electrochemical Performance of Single-Crystal LiNiO2 Cathodes, Chemistry of Materials, 36(3), pp. 1497-1512. https://doi.org/10.1021/acs.chemmater.3c02727
APA Citation style: Karger, L., Korneychuk, S., van den Bergh, W., Dreyer, S., Zhang, R., Kondrakov, A., Janek, J., & Brezesinski, T. (2023). Seesaw Effect of Substitutional Point Defects on the Electrochemical Performance of Single-Crystal LiNiO2 Cathodes. Chemistry of Materials. 36(3), 1497-1512. https://doi.org/10.1021/acs.chemmater.3c02727
