Abstract
The thick electrode design is preferential in high-energy lithium-ion batteries(LIBs) systems.However,the sluggish ionic transport in homogeneous porous thick electrodes severely limits the areal capacity at high charging/discharging rates.The hierarchical porous design is a promising approach to mitigate kinetic limitations because it can distribute mass effectively in natural systems.In this study,the effects of bimodal microscale pores are fully investigated in thick electrodes from both architectural and electrochemical perspectives.Notably,by introduction of the bimodal microscale porous structure,the rate capability improves remarkably in thick electrodes with a low porosity(39%).By combining experimental results with simulations,this work presents a rational design guideline for preparing thick electrodes with a porosity at the commercial level,as well as simultaneous high energy and power densities,which brings new insights into the advanced electrode architecture design in scalable high-energy and high-power energy storage systems for practical applications.
NSTL