Modelling interfacial ionic transport in Li2VO2F cathodes during battery operation†

IF 3.2 Q2 CHEMISTRY, PHYSICAL Energy advances Pub Date : 2024-07-30 DOI:10.1039/D4YA00163J
Jolla Kullgren, Jin Hyun Chang, Simon Loftager, Shweta Dhillon, Tejs Vegge and Daniel Brandell
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Abstract

Transition metal oxyflourides have gained considerable interest as potential high-capacity cathode materials for Li-ion batteries. So far, commercialization has been hindered by the poor cyclability and fast degradation of this class of materials. The degradation process is believed to start at the surface and progresses toward the bulk. In this context, a suitable cathode-electrolyte interphase (CEI) appears to be a crucial factor where the formation of LiF has been identified as a key component promoting interfacial stability. In the current work, we make use of a combined density functional theory (DFT) and kinetic Monte Carlo (kMC) approach. Using DFT, we determine relevant interfaces between Li2VO2F and LiF. Rejection-free kMC simulations with parameters based on DFT are then used to probe the kinetics in the charging and discharging process of the Li2VO2F phase. We find that the interface formed by joining Li2VO2F and LiF via their most stable surface terminations has a modest but positive effect on the charging rate, where the LiF phase acts as a funnel that facilitates the Li extraction from the bulk of the Li2VO2F phase. However, the same interface has a severe impeding effect on the discharging of partially delithiated structures, which is orders of magnitudes slower than in the charging process. We find that the key property controlling the kinetics in the discharging process is the difference in stability of Li vacancies in the Li2VO2F and LiF phases.

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电池运行过程中 Li2VO2F 阴极的界面离子传输建模
作为锂离子电池的潜在高容量阴极材料,过渡金属氧氟化物已引起了人们的极大兴趣。迄今为止,这一类材料循环性差、降解快,阻碍了其商业化。降解过程被认为是从表面开始,然后向块体发展。在这种情况下,合适的阴极-电解质间相(CEI)似乎是一个关键因素,而 LiF 的形成被认为是促进界面稳定性的一个关键因素。在目前的工作中,我们采用了密度泛函理论(DFT)和动力学蒙特卡罗(kMC)相结合的方法。利用 DFT,我们确定了 Li2VO2F 和 LiF 之间的相关界面。然后使用基于 DFT 参数的无排斥 kMC 模拟来探究 Li2VO2F 相充放电过程的动力学。我们发现,Li2VO2F 和 LiF 通过其最稳定的表面端点连接形成的界面对充电速率有适度但积极的影响,其中 LiF 相起到漏斗的作用,有助于从 Li2VO2F 相的主体中提取锂。然而,同一界面对部分脱锂化结构的放电具有严重的阻碍作用,放电速度比充电过程慢几个数量级。我们发现,控制放电过程动力学的关键特性是 Li2VO2F 和 LiF 相中锂空位稳定性的差异。
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Correction: Steady states and kinetic modelling of the acid-catalysed ethanolysis of glucose, cellulose, and corn cob to ethyl levulinate. Back cover Fabrication methods, pseudocapacitance characteristics, and integration of conjugated conducting polymers in electrochemical energy storage devices Inside back cover Back cover
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