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Multiscale coupling of surface temperature with solid diffusion in large lithium-ion pouch cells

Jie Lin, Howie N. Chu, David A. Howey, Charles W. Monroe

2022Communications Engineering34 citationsDOIOpen Access PDF

Abstract

Abstract Untangling the relationship between reactions, mass transfer, and temperature within lithium-ion batteries enables approaches to mitigate thermal hot spots and slow degradation. Here, we develop an efficient physics-based three-dimensional model to simulate lock-in thermography experiments, which synchronously record the applied current, cell voltage, and surface-temperature distribution from commercial lithium iron phosphate pouch cells. We extend an earlier streamlined model based on the popular Doyle–Fuller–Newman theory, augmented by a local heat balance. The experimental data reveal significant in-plane temperature non-uniformity during battery charging and discharging, which we rationalize with a multiscale coupling between heat flow and solid-state diffusion, in particular microscopic lithium intercalation within the electrodes. Simulations are exploited to quantify properties, which we validate against a fast full-discharge experiment. Our work suggests the possibility that non-uniform thermal states could offer a window into—and a diagnostic tool for—the microscopic processes underlying battery performance and cycle life.

Topics & Concepts

Lithium (medication)Materials sciencePouchDiffusionIonCoupling (piping)Surface (topology)ThermodynamicsChemistryComposite materialPhysicsGeologyGeometryMathematicsMedicinePaleontologyEndocrinologyOrganic chemistryAdvancements in Battery MaterialsAdvanced Battery Technologies ResearchAdvanced Battery Materials and Technologies
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