Understanding reactions at the electrode/electrolyte interface (EEI) is essential to developing strategies to enhance cycle life and safety of lithium batteries. Despite research in the past four decades, there is still limited understanding by what means different components are formed at the EEI and how they influence EEI layer properties. We review findings used to establish the well-known mosaic structure model for the EEI (often referred to as solid electrolyte interphase or SEI) on negative electrodes including lithium, graphite, tin, and silicon. Much less understanding exists for EEI layers for positive electrodes. High-capacity Li-rich layered oxides yLi2-xMnO3·(1-y)Li1-xMO2, which can generate highly reactive species toward the electrolyte via oxygen anion redox, highlight the critical need to understand reactions with the electrolyte and EEI layers for advanced positive electrodes. Recent advances in in situ characterization of well-defined electrode surfaces can provide mechanistic insights and strategies to tailor EEI layer composition and properties.
The (electro)chemical
reactions between positive electrodes and
electrolytes are not well understood. We examined the oxidation of
a LiPF6-based electrolyte with ethylene carbonate (EC)
with layered lithium nickel, manganese, and cobalt oxides (NMC). Density
functional theory calculations showed that the driving force for EC
dehydrogenation on oxides, yielding surface protic species, increased
with greater Ni content in NMC. Ex situ infrared and Raman spectroscopy
revealed experimental evidence for EC dehydrogenation on charged NMC
surfaces. Protic species on charged NMC surfaces from EC dehydrogenation
could further react with LiPF6 to generate less-coordinated
F species such as PF3O-like and lithium nickel oxyfluoride
species on charged NMC particles and HF and PF2O2
– in the electrolyte. Larger degree of salt decomposition
was coupled with increasing EC dehydrogenation on charged NMC with
increasing Ni or lithium deintercalation. An oxide-mediated chemical
oxidation of electrolytes was proposed, providing new insights in
stabilizing high-energy positive electrodes and improving Li-ion battery
cycle life.
International audienceA Si-based anode with improved performance can be achieved using high-energy ball-milling as a cheap and easy process to produce Si powders prepared from a coarse-grained material. Ball-milled powders present all the advantages of nanometric Si powders, but not the drawbacks. Milled powders are nanostructured with micrometric agglomerates (median size [similar]10 μm), made of submicrometric cold-welded particles with a crystallite size of [similar]10 nm. The micrometric particle size provides handling and non-toxicity advantages compared to nanometric powders, as well as four times higher tap density. The nanostructuration is assumed to provide a shortened Li+ diffusion path, a fast Li+ diffusion path along grain boundaries and a smoother phase transition upon cycling. Compared to non-milled 1-5 μm powders, the improved performance of nanostructured milled Si powders is linked to a strong lowering of particle disconnection at each charge, while the irreversibility due to SEI formation remains unchanged. An electrode prepared in acidic conditions with the CMC binder achieves 600 cycles at more than 1170 mA h per gram of the milled Si-based electrode, in an electrolyte containing FEC/VC SEI-forming additives, with a coulombic efficiency above 99%, compared to less than 100 cycles at the same capacity for an electrode containing nanometric Si powder
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