Abstract
A general framework to study the effects of chemical reaction, local deformation velocity and their interaction on the two-way coupling between stress and Li diffusion in a spherical silicon electrode under galvanostatic operation is presented in this work. The reversible chemical theory is adopted as a start up to obtain the reaction equation and the influence of local deformation velocity on the flux is taken into consideration. This is such a complex problem that an analytical solution can hardly be found. Therefore, a numerical method is subsequently used to solve the derived coupled partial differential equations (PDEs) in nonlinear elasticity with finite deformation to analyze the diffusion-induced stress (DIS) in the electrode. The numerical results of lithium concentration, radial stress and hoop stress suggest that in comparison with the local deformation velocity, the reversible chemical reaction plays a much more significant role in altering the distribution of DIS and Li concentration. The local deformation could raise the concentration gradient and result in larger magnitude of DIS, while the chemical reaction could hinder the diffusion process as well as the swelling of the electrode material. It is also observed that the local deformation could promote the chemical reaction near the surface of the electrode but retard it in the core. Furthermore, the effects of the current density are also discussed. For a smaller lithiation rate, the interaction between chemical reaction and local deformation has a tendency of decreasing, which could have significant contribution to enhance the stability level and the cycle performance of lithium-ion batteries.
Highlights
Among all kinds of energy storage devices, rechargeable lithium batteries have achieved spectacular commercial success in portable electronic devices, electric-based transportation and the medical devices with portable implantation due to their high energy capacity, long cycle life as well as low cost and environmental friendliness
Lithiation of silicon is a typical instance of complicated multifield coupled process, which is the result of the interaction of multiple factors including reversible chemical reaction, lithium diffusion, considerable local deformation, etc
The radial stress as well as the hoop stress are normalized in the form of PR∗=3(1-υ)DPR/EΩj0R0 and Pθ∗= 3(1-υ)DPθ/EΩj0R0, and the dimensionless radial displacement and dimensionless velocity are expressed as u∗=u/R0 and v∗=vR0/D respectively, along with the dimensionless radial coordinates employed as R∗=R/R0
Summary
Among all kinds of energy storage devices, rechargeable lithium batteries have achieved spectacular commercial success in portable electronic devices, electric-based transportation and the medical devices with portable implantation due to their high energy capacity, long cycle life as well as low cost and environmental friendliness. During the process of electrochemical charging, silicon will swell more than three times to its initial volume.1,2 Such severe volumetric change, if not accommodated by proper deformation, can undoubtedly introduce mechanical stresses which may lead to the rapid fading of the electrodes, imposing a great challenge in controlling electrochemical-structural reliability of lithium-ion batteries. Lithiation of silicon is a typical instance of complicated multifield coupled process, which is the result of the interaction of multiple factors including reversible chemical reaction, lithium diffusion, considerable local deformation, etc. The effects of reversible chemical reaction, the local deformation velocity as well as their interaction on the stress evolution process and the lithium diffusion in the spherical electrode of a lithium-ion battery are investigated respectively in nonlinear elasticity with finite deformation. For the reason that the local velocity is dependent on the rates of charging/discharging, the influence of it on the stress evolution and the diffusion process is discussed separately in this paper
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