Electrochemical Modeling and Experimental Verification of Lithiation Gradients in Oxide Cathodes of Lithium-Ion Cells

• Main Authors: Abraham, D.P (Author), Okasinski, J.S (Author), Rodrigues, M.-T.F (Author), Shkrob, I.A (Author)
• Format: Article
• Language: English
• Published: IOP Publishing Ltd 2022
• Subjects: Cathodes; Cobalt compounds; Electrochemical modeling; Experimental verification; Li-ion cells; Lithiation; Lithium; Lithium-ion batteries; Lithium-ion cells; Manganese oxide; Model verification; Nickel oxide; Operando; Oxide cathode; Positive electrodes; Profilometry; X- ray diffractions
• Online Access: View Fulltext in Publisher

 Lithiated nickel-cobalt-manganese oxides, such as NCM523, are used in the positive electrode (cathode) of Li-ion cells. Using operando X-ray diffraction profilometry, lithiation gradients in the cathode matrix can be observed and quantified by expansion into Legendre polynomials with time-dependent weights. These weights (referred to as gradients) increase in magnitude when electric current flows through the cell, decrease during potentiostatic hold and finally relax to zero when the current is interrupted during open circuit rest. Both physics-based electrochemical models and operando X-ray experiments suggest that the time constants for gradient growth and abatement are primarily determined by ionic diffusion in the oxide particles, which in turn depends on their lithium content. In contrast, the magnitude of gradients depends mainly on the applied current. The X-ray profilometry provides a way of directly probing the formation and disappearance of Li gradients across the cathode during fast cycling, which can help to diagnose the effects of material degradation in the cells. © 2022 Electrochemical Society Inc.. All rights reserved.