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Efficient Reformulation of Linear and Nonlinear Solid-Phase Diffusion in Lithium-ion Battery Models using Symmetric Polynomials: Mass Conservation and Computational Efficiency

Raghav Sai Thiagarajan, Akshay Subramaniam, Suryanarayana Kolluri, Taylor R. Garrick, Yuliya Preger, Valerio De Angelis, Jin-hyung Lim, Venkat R. Subramanian

2022Journal of The Electrochemical Society16 citationsDOIOpen Access PDF

Abstract

Lithium-ion batteries are typically modeled using porous electrode theory coupled with various transport and reaction mechanisms, along with suitable discretization or approximations for the solid-phase diffusion equation. The solid-phase diffusion equation represents the main computational burden for typical pseudo-2-dimensional (p2D) models since these equations in the pseudo r -dimension must be solved at each point in the computational grid. This substantially increases the complexity of the model as well as the computational time. Traditional approaches towards simplifying solid-phase diffusion possess certain significant limitations, especially in modeling emerging electrode materials which involve phase changes and variable diffusivities. A computationally efficient representation for solid-phase diffusion is discussed in this paper based on symmetric polynomials using Orthogonal Collocation and Galerkin formulation (weak form). A systematic approach is provided to increase the accuracy of the approximation (p form in finite element methods) to enable efficient simulation with a minimal number of semi-discretized equations, ensuring mass conservation even for non-linear diffusion problems involving variable diffusivities. These methods are then demonstrated by incorporation into the full p2D model, illustrating their advantages in simulating high C-rates and short-time dynamic operation of Lithium-ion batteries.

Topics & Concepts

DiscretizationCollocation (remote sensing)DiffusionApplied mathematicsFinite element methodNonlinear systemPhase (matter)Diffusion equationMathematicsComputer scienceMathematical analysisChemistryPhysicsThermodynamicsEngineeringOrganic chemistryMachine learningOperations managementQuantum mechanicsMetric (unit)Advanced Battery Technologies ResearchAdvancements in Battery MaterialsAdvanced Battery Materials and Technologies
Efficient Reformulation of Linear and Nonlinear Solid-Phase Diffusion in Lithium-ion Battery Models using Symmetric Polynomials: Mass Conservation and Computational Efficiency | Litcius