Unravelling the convoluted and dynamic interphasial mechanisms on Li metal anodes.
Sha TanJu-Myung KimAdam A CorraoSanjit GhoseHui ZhongNing RuiXuelong WangSanjaya SenanayakeBryant J PolzinPeter G KhalifahJie XiaoJun LiuKang XuXiao-Qing YangXia CaoEnyuan HuPublished in: Nature nanotechnology (2022)
Accurate understanding of the chemistry of solid-electrolyte interphase (SEI) is key to developing new electrolytes for high-energy batteries using lithium metal (Li 0 ) anodes 1 . SEI is generally believed to be formed by the reactions between Li 0 and electrolyte 2,3 . However, our new study shows this is not the whole story. Through synchrotron-based X-ray diffraction and pair distribution function analysis, we reveal a much more convoluted formation mechanism of SEI, which receives considerable contributions from electrolyte, cathode, moisture and native surface species on Li 0 , with highly dynamic nature during cycling. Using isotope labelling, we traced the origin of LiH to electrolyte solvent, moisture and a new source: the native surface species (LiOH) on pristine Li 0 . When lithium accessibility is very limited as in the case of anode-free cells, LiOH develops into plate-shaped large crystals during cycling. Alternatively, when the lithium source is abundant, as in the case of Li||NMC811 cells, LiOH reacts with Li 0 to form LiH and Li 2 O. While the desired anion-derived LiF-rich SEI is typically found in the concentrated electrolytes or their derivatives, we found it can also be formed in low-concentration electrolyte via the crosstalk effect, emphasizing the importance of formation cycle protocol and opening up opportunities for low-cost electrolyte development.
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