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Phase Stability of Li-rich Layered Cathodes: Insight into the Debate over Solid Solutions vs Phase Separation

Zhi Lu, Shiqiang Hao, Ziliang Wang, Hyungjun Kim, Christopher Wolverton

2024Chemistry of Materials10 citationsDOI

Abstract

Li-rich layered transition metal oxides (Li 1+ x M 1– x O 2 or m Li 2 MnO 3 – n LiMO 2 ) have been widely studied as cathode materials for Li-ion batteries recently due to their enhanced capacity of larger than 250 mAh g –1 . However, even the qualitative nature of the phase stability of these materials, whether they form a solid solution or are phase separated, has been the subject of intense debate. In this work, we use density functional theory calculations to investigate the phase stability of these Li-rich layered transition metal oxides (Li 2 MnO 3 –LiMO 2, M = Co, Ni, Mn). We calculate the mixing enthalpy and coherency strain energy between Li 2 MnO 3 and LiMO 2 for two distinct cases: (1) mixing of M on the Li and Mn sites respectively in the transition metal layer of Li 2 MnO 3, resulting in a solid solution with C 2/ m symmetry, and (2) mixing of Li and Mn on the M sites of LiMO 2, resulting in a solid solution with R 3̅ m symmetry. We show that phase separation is energetically preferred relative to a solid solution at T = 0 K, and the coherency strain energy has little influence on phase stability. Results also display that a solid solution with R 3̅ m symmetry has a larger mixing enthalpy than that with C 2/ m symmetry at T = 0 K. Furthermore, we use the mixing enthalpies along with mean-field mixing entropies to calculate free energies and phase diagrams. At low temperature, the system exhibits phase separation between the C 2/ m and R 3̅ m phases, with appreciable solubility in each phase, and at high temperature, there is a transformation to the single-phase R 3̅ m solid solution. For high Li content compositions, the phase diagram shows a region of stability for the single phase C 2/ m solid solution. Our calculations support one possible explanation for the discrepancies between various reports of the structure of these Li-rich layered materials; the compositions and temperatures of these synthesized materials could be close to phase boundaries separating the regions of solid solution vs phase-separation. The calculated phase diagrams also indicate that the phase stability of Li-rich layered materials largely depends on the synthesis temperature, the amount of excess Li, and the combination of transition metals.

Topics & Concepts

Phase (matter)CathodeMaterials scienceSeparation (statistics)Solid solutionStability (learning theory)Chemical engineeringNanotechnologyChemistryPhysical chemistryComputer scienceMetallurgyEngineeringOrganic chemistryMachine learningAdvancements in Battery MaterialsAdvanced Battery Materials and TechnologiesExtraction and Separation Processes
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