Keywords
Li-ion battery, electrode fabrication, electronic conductivity, ionic resistance, contact resistance, binder migration, drying, calendering
Abstract
The drying process of electrodes might seem to be a simple operation, but it has profound effects on the microstructure. Some unexpected changes can happen depending on the drying conditions. In prior work, we developed the multiphase-smoothed-particle (MPSP) model, which predicted a relative increase in the carbon additive and binder adjacent to the current collector during drying. This motivated us to undertake the present experimental investigation of the relationship between the drying rate and microstructure and transport properties for a typical anode and cathode. Specifically, the drying rate was controlled by means of temperature for both an NMC532 cathode and graphite anode. The material distribution was analyzed using a combination of cross-section SEM images and the energy-dispersive X-ray spectroscopy elemental maps. The binder concentration gradients were developed in both the in- and through-plane directions. The through-plane gradient is evident at a temperature higher than 150 °C, whereas the in-plane variations resulted at all drying temperatures. The measurements identified an optimum temperature (80 °C) that results in high electronic conductivity and low ionic resistivity due to a more uniform binder distribution. Trends in transport properties are not significantly altered by calendering, which highlights the importance of the drying rate itself on the assembled cell properties.
Original Publication Citation
Nikpour, M., Liu, B., Minson, P., Hillman, Z., Mazzeo, B. A., & Wheeler, D. R. (2022). Li-ion Electrode Microstructure Evolution during Drying and Calendering. Batteries, 8(9), 107. https://doi.org/10.3390/batteries8090107
BYU ScholarsArchive Citation
Nikpour, Mojdeh; Liu, Baichuan; Minson, Paul; Hillman, Zachary; Mazzeo, Brian A.; and Wheeler, Dean R., "Li-ion Electrode Microstructure Evolution during Drying and Calendering" (2022). Faculty Publications. 7733.
https://scholarsarchive.byu.edu/facpub/7733
Document Type
Peer-Reviewed Article
Publication Date
2022-09-01
Publisher
MDPI
Language
English
College
Ira A. Fulton College of Engineering
Department
Chemical Engineering
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