Elevating Li-ion battery paradigms: Sophisticated ionic architectures in lithium-excess layered oxides for unprecedented electrochemical performance

Elevating Li-ion battery paradigms: Sophisticated ionic architectures in lithium-excess layered oxides for unprecedented electrochemical performance

In exploring the frontier of high-energy-density cathode materials for lithium-ion batteries, substantial progress has been made by fine-tuning the composition of Ni-rich cathodes tailored for high-capacity operation. Equally promising are Li-rich cathode materials, which leverage the novel mechanis...

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Main Authors: Jun Ho Yu, Konstantin Köster, Natalia Voronina, Sungkyu Kim, Hyeon-Ji Shin, Kyung Sun Kim, Kyuwook Ihm, Hyungsub Kim, Hun-Gi Jung, Koji Yazawa, Olivier Guillon, Pierluigi Gargiani, Laura Simonelli, Payam Kaghazchi, Seung-Taek Myung
Format: Article
Language:English
Published: KeAi Communications Co. Ltd. 2025-07-01
Series:eScience
Subjects:
Li excess
Layer
Cathode
Lithium
Battery
Online Access:http://www.sciencedirect.com/science/article/pii/S2667141725000060
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Summary:In exploring the frontier of high-energy-density cathode materials for lithium-ion batteries, substantial progress has been made by fine-tuning the composition of Ni-rich cathodes tailored for high-capacity operation. Equally promising are Li-rich cathode materials, which leverage the novel mechanism of oxygen-redox chemistry to achieve enhanced capacities. Nonetheless, the practical realization of these capacities remains elusive, falling short of the desired benchmarks. In this work, we pioneer a Mn-based, Co-free, reduced-nickel, high-capacity cathode material: Li0.75[Li0.15Ni0.15Mn0.7]O2 ionic exchanged from Na0.75[Li0.15Ni0.15Mn0.7]O2. This material is an O2-type layered structure, distinguished by honeycomb ordering within the transition-metal layer, as confirmed by comprehensive neutron and X-ray studies and extensive electrostatic screening. The material's unique structural integrity facilitates the delivery of an exceptional quantity of Li+ ions via O2−/O2n− redox, circumventing oxygen release and phase transition. The de/lithiation process enables the delivery of a substantial reversible capacity of ∼284 ​mAh ​(g-oxide)−1 (956 ​Wh ​(kg-oxide)−1). Moreover, this structural and chemical stability contributes to an acceptable cycling stability for 500 ​cycles in full cells, providing improved thermal stability with lower exothermic heat generation and thus highlighting the feasibility of a Mn-based, Co-free, reduced-nickel composition. This investigation marks a pivotal advancement in layered lithium cathode materials.
ISSN:2667-1417

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