Litcius/Paper detail

Machine-learning-revealed statistics of the particle-carbon/binder detachment in lithium-ion battery cathodes

Zhisen Jiang, Jizhou Li, Yang Yang, Linqin Mu, Chenxi Wei, Xiqian Yu, P. Pianetta, Kejie Zhao, Peter Cloetens, Feng Lin, Yijin Liu

2020Nature Communications254 citationsDOIOpen Access PDF

Abstract

The microstructure of a composite electrode determines how individual battery particles are charged and discharged in a lithium-ion battery. It is a frontier challenge to experimentally visualize and, subsequently, to understand the electrochemical consequences of battery particles' evolving (de)attachment with the conductive matrix. Herein, we tackle this issue with a unique combination of multiscale experimental approaches, machine-learning-assisted statistical analysis, and experiment-informed mathematical modeling. Our results suggest that the degree of particle detachment is positively correlated with the charging rate and that smaller particles exhibit a higher degree of uncertainty in their detachment from the carbon/binder matrix. We further explore the feasibility and limitation of utilizing the reconstructed electron density as a proxy for the state-of-charge. Our findings highlight the importance of precisely quantifying the evolving nature of the battery electrode's microstructure with statistical confidence, which is a key to maximize the utility of active particles towards higher battery capacity.

Topics & Concepts

Battery (electricity)ElectrodeCathodeMicrostructureMaterials scienceLithium-ion batteryIonParticle (ecology)Computer scienceLithium (medication)Electrical conductorElectrochemistryNanotechnologyComposite materialElectrical engineeringPhysicsEngineeringPower (physics)ThermodynamicsOceanographyEndocrinologyQuantum mechanicsMedicineGeologyAdvanced Battery Technologies ResearchAdvancements in Battery MaterialsMachine Learning in Materials Science