Coupled electrochemical-mechanical modeling with strain gradient plasticity for lithium-ion battery electrodes
DOI10.1016/J.EUROMECHSOL.2021.104230zbMath1472.74054OpenAlexW3127823361MaRDI QIDQ2035208
Chunsheng Lu, Lizhong Sun, Zengsheng Ma, Hui Wu, Yan Wang, Wen-Juan Jiang
Publication date: 24 June 2021
Published in: European Journal of Mechanics. A. Solids (Search for Journal in Brave)
Full work available at URL: https://doi.org/10.1016/j.euromechsol.2021.104230
finite difference methodstrain gradient plasticitydiffusion-induced stressreaction dislocationspherical electrode
Plastic materials, materials of stress-rate and internal-variable type (74C99) Finite difference methods applied to problems in solid mechanics (74S20) Technical applications of optics and electromagnetic theory (78A55) Chemical structure in solid mechanics (74E40)
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Cites Work
- A numerical basis for strain-gradient plasticity theory: Rate-independent and rate-dependent formulations
- Size effect in micro-scale cantilever beam bending
- A phenomenological theory for strain gradient effects in plasticity
- Grain-size effect in viscoplastic polycrystals at moderate strains
- Indentation size effects in crystalline materials: a law for strain gradient plasticity
- A polycrystal plasticity model based on the mechanical threshold
- Thermodynamic coupling between gradient elasticity and a Cahn-Hilliard type of diffusion: size-dependent spinodal gaps
- Mechanism-based strain gradient plasticity. I: Theory
- Mechanism-based strain gradient plasticity. II: Analysis
- Incompatibility and a simple gradient theory of plasticity
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