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Cracking and associated volumetric expansion of NMC811 secondary particles

Siamak S. Shishvan, N.A. Fleck, Robert M. McMeeking, V.S. Deshpande

2023Journal of Power Sources46 citationsDOIOpen Access PDF

Abstract

Secondary particles comprising a large number of nickel-rich single crystal primary particles are extensively used as storage particles in cathodes of lithium-ion batteries. It is well-established that crack formation in secondary particles is an important degradation mode that contributes to decline in battery performance. Recent X-ray tomographic observations suggest that, at very low C-rates, concentration gradients of lithium within an NMC811 secondary particle are negligible yet cracking still occurs. Additionally, during delithiation the primary particles shrink yet a volumetric expansion of the secondary particle occurs. These observations are explained by a numerical model of distributed cracking due to the extreme anisotropy of lithiation strain of primary particles. The incompatible deformation from grain to grain induces large self-stresses even in the absence of spatial gradients in the lithium concentration. The stress state is sufficient to drive a dynamic catastrophic fracture event, and the associated kinetic energy acquired by the primary particles moves them apart (akin to an explosive event) with the carbon and binder domain surrounding each secondary particle restricting the outward motion of the primary particles. It is predicted that a volume expansion of the secondary particles on the order of 20 % accompanies cracking, in agreement with recently reported observations.

Topics & Concepts

CrackingMaterials scienceParticle (ecology)Lithium (medication)Stress (linguistics)Fracture (geology)Composite materialGeologyMedicineEndocrinologyOceanographyLinguisticsPhilosophyAdvanced Battery Technologies ResearchAdvancements in Battery MaterialsExtraction and Separation Processes
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