Sangwoo Han scite author profile

The mechanical instability of the Solid Electrolyte Interphase (SEI) layer in lithium ion (Li-ion) batteries causes significant side reactions resulting in Li-ion consumption and cell impedance rise by forming further SEI layers, which eventually leads to battery capacity fade and power fade. In this paper, the composition-/structure-dependent elasticity of the SEI layer is investigated via Atomic Force Microscopy (AFM) measurements coupled with X-ray Photoelectron Spectroscopy (XPS) analysis, and atomistic calculations. It is observed that the inner layer is stiffer than the outer layer. The measured Young's moduli are mostly in the range of 0.2 to 4.5 GPa, while some values above 80 GPa are also observed. This wide variation of the observed elastic modulus is elucidated by atomistic calculations with a focus on chemical and structural analysis. The numerical analysis shows the Young's moduli range from 2.4 GPa to 58.1 GPa in the order of the polymeric, organic, and amorphous inorganic components. The crystalline inorganic component (LiF) shows the highest value (135.3 GPa) among the SEI species. This quantitative observation on the elasticity of individual components of the SEI layer must be essential to analyzing the mechanical behavior of the SEI layer and to optimizing and controlling it.

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Micro-Scale Modeling of Li-Ion Batteries: Parameterization and Validation

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Seo

Han

et al. 2012

J. Electrochem. Soc.

133

131

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A fully parameterized microscale model for lithium ion cells is presented in which the solid and pores (filled by electrolyte) are spatially resolved, and the mass and charge transport equations describing diffusion and migration in each phase are solved separately. Such a model allows: (1) the correlation of structure-scale, non-homogeneous material properties with macroscopic battery performance, and (2) the correlation of geometrical electrode morphology with macroscopic battery performance (electrode design). The micro-model approach discussed here allows for a simpler parameterization as fewer constitutive relations are needed in contrast to the macro-homogenous physical-based approaches. Input parameters were measured experimentally on lithium manganese oxide electrodes and LiPF 6 in 3:7 EC:DMC. Verification and validation for the model is also reported.

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Numerical study of grain boundary effect on Li+ effective diffusivity and intercalation-induced stresses in Li-ion battery active materials

Han

Park

et al. 2013

Journal of Power Sources

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Application of artificial neural networks in design of lithium-ion batteries

Han

Shin

et al. 2018

Journal of Power Sources

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In situ atomic force microscopy studies on lithium (de)intercalation-induced morphology changes in Li CoO2 micro-machined thin film electrodes

Park

Kalnaus

Han

et al. 2013

Journal of Power Sources

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Sangwoo Han

Component-/structure-dependent elasticity of solid electrolyte interphase layer in Li-ion batteries: Experimental and computational studies

Micro-Scale Modeling of Li-Ion Batteries: Parameterization and Validation

Numerical study of grain boundary effect on Li+ effective diffusivity and intercalation-induced stresses in Li-ion battery active materials

Application of artificial neural networks in design of lithium-ion batteries

In situ atomic force microscopy studies on lithium (de)intercalation-induced morphology changes in Li CoO2 micro-machined thin film electrodes

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