探索过量锂无序岩盐（DRX）正极材料合成新途径

IF 5.2 Q2 MATERIALS SCIENCE, MULTIDISCIPLINARY

Materials Advances Pub Date : 2025-04-23 DOI:10.1039/D4MA01287A

Matthew S. Chambers, Tianyu Li, Zhilin Liang, Jong Keum, Kevin H. Stone, Raphaële J. Clément, Beth L. Armstrong and Ethan C. Self

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引用次数: 0

摘要

过量锂无序岩盐（DRX）材料因其高比能（800+ W h kg - 1）和成分灵活性而成为无Co/ ni锂离子阴极的有希望的候选者。DRX阴极通常是用固态反应合成的，这种反应很难规模化，而且对颗粒形态几乎没有控制。为了解决这一瓶颈，本研究报告了一种两步法的溶液反应路线，以制备Mn/ ti基DRX氟化氧阴极，其标称成分为Li1.25Mn0.5Ti0.3O1.95F0.05和Li1.35Mn0.7Ti0.1O1.85F0.15。更具体地说，甘氨酸-硝酸盐燃烧反应用于生产锂化过渡金属氧化物，该氧化物进一步与liff反应以生产高纯度的DRX粉末。值得注意的是，在800-1000°C下退火1小时后，该路线得到80-90%纯度的DRX，并且19F固态核磁共振（ssNMR）光谱表明，F−阴离子成功地融入到DRX结构中。用这种方法制备的阴极表现出很好的电化学性能，Li1.35Mn0.7Ti0.1O1.85F0.15的可逆容量达到~ 210 mA h g - 1，在半电池中具有中等的循环稳定性（150次循环后容量保持65%）。总的来说，这些结果表明，利用新型金属氧化物前驱体是一种可行的、很大程度上尚未开发的生产高性能无Co/ ni DRX阴极的方法。

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Exploring a new synthesis route to lithium-excess disordered rock salt (DRX) cathode materials†

Lithium-excess disordered rock salt (DRX) materials are promising candidates for Co/Ni-free Li-ion cathodes due to their high specific energy (800+ W h kg⁻¹) and compositional flexibility. DRX cathodes are typically synthesized using solid-state reactions, which are difficult to scale and provide little-to-no control over particle morphology. To address this bottleneck, the present study reports a two-step, solution-based reaction route to prepare Mn/Ti-based DRX oxyfluoride cathodes with nominal compositions of Li_1.25Mn_0.5Ti_0.3O_1.95F_0.05 and Li_1.35Mn_0.7Ti_0.1O_1.85F_0.15. More specifically, a glycine–nitrate combustion reaction is used to produce a lithiated transition metal oxide, which is further reacted with LiF to produce high-purity DRX powders. Remarkably, this route yields 80–90% pure DRX after annealing for 1 h at 800–1000 °C, and ¹⁹F solid-state nuclear magnetic resonance (ssNMR) spectra demonstrate that F⁻ anions are successfully incorporated into the DRX structure. Cathodes prepared using this approach exhibit promising electrochemical performance, with Li_1.35Mn_0.7Ti_0.1O_1.85F_0.15 attaining reversible capacities ∼210 mA h g⁻¹ and moderate cycling stability in half cells (65% capacity retention over 150 cycles). Overall, these results demonstrate that utilizing novel metal oxide precursors presents a viable and largely unexplored method to produce high-performance Co/Ni-free DRX cathodes.