The dispersion quality and the storage stability of the electrode slurry are very important industrial issues as they directly affect the productivity of the electrode process as well as the performance of the battery. To maintain the dispersion stability, the prepared electrode slurry is agitated in a storage tank before entering the subsequent coating process. However, our understanding on the dispersibility of electrode slurries during storage is not enough. In this study, we systematically investigate the changes in the dispersion state and the rheological properties of Ni-rich NMC-based cathode slurries under various agitating conditions during storage. Most of the conductive nanoparticles form large spherical agglomerates of several tens of micrometers under low-speed agitating conditions, resulting in a dramatic change in the rheological properties. We also report that the change in the dispersion state and the rheological properties during storage can be characterized by the hydrodynamic stress induced by the flow. The mechanism of change in the microstructure of the cathode slurry during storage can be understood by considering the relative affinity between the particles and the flow characteristics during agitation. This study clearly demonstrates how the cathode slurry should be cared during storage to prevent quality problems.
The nonlinear rheology of concentrated lithium-ion battery anode slurry was examined under large amplitude oscillatory shear and interpreted with a sequence of physical process (SPP) analysis. The complex interplay of three anode slurry components-graphite (Gr) as the active material, carbon black (CB) as the conductive additive, and carboxymethyl cellulose (CMC) as the binder-leads to a two-step yielding behavior, represented as the secondary plateau in dynamic strain and stress sweep tests. We demonstrate that the two-step yielding behavior is manifested as double deltoids in the SPP analysis, through the study of intra-cycle rheological transition under oscillatory shear flow. Slurries of Gr-CMC exhibit two-step yielding behavior; slurries of CB-CMC do not, suggesting that Gr and CMC are the primary causes of two-step yielding in an anode slurry. A sedimentation test on a dilute Gr-CMC solution yielded phase separation between graphite particles, with CMC adsorbed on their surface and graphite particles aggregated via hydrophobic attraction. This indicates two possible types of interactions in a concentrated slurry: a hydrophobic interaction between graphite particles and a physical interaction caused by CMC adsorbed on graphite particles. The first yielding step relates to the hydrophobic attraction between graphite particles, resulting in a network structure that is expected to be brittle and rupture at a small strain. The second yielding step is attributed to the interaction between concentrated CMC, which is corroborated by the overlap of the secondary deltoid of the anode slurry and the single deltoid of the concentrated CMC solution in the SPP analysis.
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