Transport and Reaction of Electrons and Molecules in Solid Electrolyte Interphases formed at Different Electrode Potentials: A Combined Experimental and Modeling Approach
Falk Thorsten Krauss, Annalena Duncker, Bernhard Roling

TL;DR
This study investigates how electrons and molecules move and react in SEI layers formed at different potentials in lithium-ion batteries, combining experiments and modeling.
Contribution
A combined experimental and modeling approach to elucidate transport and reaction mechanisms in SEI layers formed at different electrode potentials.
Findings
The current density ratio depends on SEI formation potential and time.
A model predicts four distinct diffusion and reaction regimes based on reaction rate constants.
Transport coefficients for electrons and molecules in SEI are estimated effectively.
Abstract
Good passivation properties of the solid electrolyte interphase (SEI) on the graphite‐based negative electrode are essential for a long cycle life of lithium‐ion batteries. Nevertheless, the underlying electron and molecule transport mechanisms inside the SEI are poorly understood. Here, we elucidate transport and reaction in model‐type SEIs formed at different electrode potentials by combining generator‐collector experiments and electrochemical impedance spectroscopy with a diffusion‐reaction modeling approach. In the generator‐collector experiments, we use a four‐electrode‐based setup to compare the electrolyte reduction current density with a redox molecule (ferrocenium Fc+) reduction current density at an SEI‐covered glassy carbon electrode. We find that the current density ratio depends on the SEI formation potential as well as on the formation time. The experimental results are…
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Taxonomy
TopicsAdvancements in Battery Materials · Advanced Battery Materials and Technologies · Advanced Battery Technologies Research
