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Article Abstract
We demonstrate that for polycrystalline LiNi0.33Mn0.33Co0.33O2 c-axis textured thin film cathodes of rechargeable lithium-ion batteries, the kinetics of Li storage and release including maximum specific capacity is determined by Li diffusion. The C-rate capability and long-term cycling behavior were investigated. The films exhibited up to 30% of the expected practical capacity even at low C-rates. However, 100% capacity was achieved at very low cycling rates below 0.01C. The capacity showed a reversible behavior with changing current density, indicating no film degradation. The C-rate capability experiment showed a square root dependence of capacities on current density, which corresponds to a diffusion-controlled process. The estimated diffusivities from the cycling experiments are independent of the current density. The Li chemical and tracer diffusivities were measured using standard electrochemical and non-electrochemical diffusion measurement techniques. Chemical diffusivities, thermodynamic factor, and hence Li tracer diffusivities were determined from potentiostatic intermittent titration (PITT) and electrochemical impedance spectroscopy (EIS) experiments as a function of electrode potential and state of charge (SOC). The diffusivities were found to be approximately independent of potential, SOC, and cycle number. The Li tracer diffusivities were validated by 6Li tracer diffusion experiments with secondary ion mass spectrometry (SIMS). The diffusivities obtained by PITT and SIMS were found to be more reliable for Li uptake and release than those obtained by EIS. Based on the diffusion results, a C-rate limit for full film delithiation below 0.01C was calculated due to slow Li diffusion.
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