Intercalation-Induced Stress and Heat Generation within Single Lithium-Ion Battery Cathode Particles

Zhang, Xiangchun; Sastry, Ann Marie; Shyy, Wei

doi:10.1149/1.2926617

Cited by 285 publications

(300 citation statements)

References 53 publications

(80 reference statements)

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“…Most continuum-level models of chemomechanical coupling have been developed to estimate diffusion-induced stresses-analogous to thermal stresses-which develop in the presence of a concentration gradient. A variety of single-particle models have been developed to estimate diffusion-induced stresses for battery electrode materials subjected to common electrochemical protocols [95][96][97] and incorporating a variety of effects including limited solid-solubility [98-100], particle shape [101,102], composition-dependent elastic modulus [103], and internal porosity [104]. Other particlelevel models have been developed which apply fracture mechanics failure criteria to study mechanical degradation of electrode materials, but these models considered static configurations-essentially the limit of zero rate-to identify critical length scales using fracture mechanics failure criteria.…”

Section: Continuum Modelingmentioning

confidence: 99%

Chemomechanics of ionically conductive ceramics for electrical energy conversion and storage

et al. 2014

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Functional materials for energy conversion and storage exhibit strong coupling between electrochemistry and mechanics. For example, ceramics developed as electrodes for both solid oxide fuel cells and batteries exhibit cyclic volumetric expansion upon reversible ion transport. Such chemomechanical coupling is typically far from thermodynamic equilibrium, and thus is challenging to quantify experimentally and computationally. In situ measurements and atomistic simulations are under rapid development to explore how this coupling can be used to potentially improve both device performance and durability. Here, we review the commonalities of coupling between electrochemical and mechanical states in fuel cell and battery materials, illustrating with specific cases the progress in materials processing, in situ characterization, and computational modeling and simulation. We also highlight outstanding questions and opportunities in these applications -both to better understand the limiting mechanisms within the materials and to significantly advance the durability and predictability of device performance required for renewable energy conversion and storage.

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Section: Continuum Modelingmentioning

confidence: 99%

Chemomechanics of ionically conductive ceramics for electrical energy conversion and storage

et al. 2014

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confidence: 98%

“…Recently, models have been developed that couple volume expansion of the active material and stresses during intercalation and deintercalation of a single porous electrode. 24,[28][29][30][31] They reveal the importance that a change in volume plays in the generation of stresses and strains, and how this may be linked to experimentally observed failure in the active material. [32][33][34][35] The model developed here accounts for the stresses that build up in porous electrodes due to volume change in the active material through the application of porous rock mechanics to porous electrode theory.…”

mentioning

confidence: 98%

“…electrode thickness) conditions. 18,[21][22][23][24][25][26][27][28][29][30][31][32][33][34][35] In many of these models, the dimensions of the porous electrode are often assumed constant and any volume changes in the active material result in only porosity changes. 21,22 Gomadam and Weidner 18 developed a model to allow both porosity and dimensional changes to occur.…”

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Modeling Volume Change in Dual Insertion Electrodes

Garrick

Huang

Srinivasan

et al. 2017

J. Electrochem. Soc.

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A mathematical model is presented that incorporates the dimensional and porosity changes in porous electrodes caused by volume changes in the active material during intercalation. Porosity and dimensional changes in an electrode can significantly affect the resistance of the battery during cycling. In addition, volume changes generate stresses in the electrode, which can lead to premature failure of the battery. Here, material conservation equations are coupled with the mechanical properties of porous electrodes to link dimensional and porosity changes to stresses and the resulting resistances that occur during the intercalation processes. Several different battery casings are examined in order to generate summary figures to aid in battery design. The associated stress, strain, porosity and resistance is predicted and discussed in relation to battery performance. Significant strides have been made to improve the range, cost, and fueling times of electric vehicles through the improvement of the design and control of cells, and several automobile manufacturers are releasing battery powered vehicles with price points that target the general public.1-10 New chemistries, such as lithium ion, have also been examined in order to increase the energy densities of these batteries in order to increase the range of battery powered vehicles, and decrease the volume displacement of these batteries in the vehicle powertrain. However, because these new chemistries result in more energy in a smaller volume, safety problems may arise.11 Therefore, it is critical to be able to predict the performance of new battery systems in order to improve safety and reliability, while also continuing to increase the energy density, which in turn decreases the weight and volume requirement of battery systems in alternative energy passenger vehicles.Due to the recent commercial and government sector success of high energy density batteries, high performance electrode materials, separators, electrolytes, and new cell and stack designs are being actively developed to further improve cell capacity, charging and discharge rates, safety, cycle life, and shelf life. The most widely used anode material (graphite) in Lithium-ion batteries undergoes a volume change (10%) during lithiation and delithiation cycles.12 However, high capacity anode materials, such as silicon and its alloys, undergo even higher volume changes ranging from 100% to 270%.12-15 Other battery chemistries, such as Li-Sn alloy intercalation cathodes, have seen volume changes as high as 350% as observed by Yang et al. 16The volume changes seen in these new battery electrode materials induce a significant amount of stress in the electrodes during battery operation.12,17-19 These volume changes and high stresses may result in the fracturing of active particles within the electrodes, and induces bulk stresses at the cell and stack level. A moderate amount of bulk stress in lithium-ion cells may be beneficial to cell operation, however, excessive stresses cause reduced cell performance an...

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“…Similarly, insertion and extraction of Li-ions in Li-battery electrodes produce large volume changes [26,27]. Most of the previous theoretical studies of strain effects in diffusional [28,29] and electrochemical systems consider this compositional lattice expansion as the only source of strain.…”

mentioning

confidence: 99%

Thermodynamics of electromechanically coupled mixed ionic-electronic conductors: Deformation potential, Vegard strains, and flexoelectric effect

et al. 2011

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Intercalation-Induced Stress and Heat Generation within Single Lithium-Ion Battery Cathode Particles

Cited by 285 publications

References 53 publications

Chemomechanics of ionically conductive ceramics for electrical energy conversion and storage

Chemomechanics of ionically conductive ceramics for electrical energy conversion and storage

Modeling Volume Change in Dual Insertion Electrodes

Thermodynamics of electromechanically coupled mixed ionic-electronic conductors: Deformation potential, Vegard strains, and flexoelectric effect

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