Abstract
Increasing electrode thickness, thus increasing the volume ratio of active materials, is one effective method to enable the development of high-energy-density Li-ion batteries. In this study, an energy density versus power density optimization of LiNi0.8Co0.15Al0.05O2 (NCA)/graphite cell stack was conducted via mathematical modeling. The energy density was found to have an inflection point versus electrode thickness at given discharging C rates. The physics-based factors that limit the energy/power density of thick electrodes were found to be increased cell polarization and underutilization of active materials. The latter is affected by Li-ion diffusion in active materials and Li-ion depletion in the electrolyte phase. Based on those findings, possible approaches were derived to surmount the limiting factors. The improvement of the energy-power relationship in an 18650 cell was used to demonstrate how to optimize the thick electrode parameters in cell engineering.
