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An XPS Study of Electrolytes for Li-Ion Batteries in Full Cell LNMO vs Si/Graphite.

Raheleh AzmiFredrik LindgrenKillian Stokes-RodriguezMihaela BugaCosmin UngureanuTom GouveiaIda ChristensenShubhadeep PalAlexandru VladAlix LadamKristina EdströmMaria Hahlin
Published in: ACS applied materials & interfaces (2024)
Two different types of electrolytes (co-solvent and multi-salt) are tested for use in high voltage LiNi 0.5 Mn 1.5 O 4 ||Si/graphite full cells and compared against a carbonate-based standard LiPF 6 containing electrolyte (baseline). Ex situ postmortem XPS analysis on both anodes and cathodes over the life span of the cells reveals a continuously growing SEI and CEI for the baseline electrolyte. The cells cycled in the co-solvent electrolyte exhibited a relatively thick and long-term stable CEI (on LNMO), while a slowly growing SEI was determined to form on the Si/graphite. The multi-salt electrolyte offers more inorganic-rich SEI/CEI while also forming the thinnest SEI/CEI observed in this study. Cross-talk is identified in the baseline electrolyte cell, where Si is detected on the cathode, and Mn is detected on the anode. Both the multi-salt and co-solvent electrolytes are observed to substantially reduce this cross-talk, where the co-solvent is found to be the most effective. In addition, Al corrosion is detected for the multi-salt electrolyte mainly at its end-of-life stage, where Al can be found on both the anode and cathode. Although the co-solvent electrolyte offers superior interface properties in terms of the limitation of cross-talk, the multi-salt electrolyte offers the best overall performance, suggesting that interface thickness plays a superior role compared to cross-talk. Together with their electrochemical cycling performance, the results suggest that multi-salt electrolyte provides a better long-term passivation of the electrodes for high-voltage cells.
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