In
battery electrolyte design principles, tuning Li+ solvation
structure is an effective way to connect electrolyte chemistry
with interfacial chemistry. Although recent proposed solvation tuning
strategies are able to improve battery cyclability, a comprehensive
strategy for electrolyte design remains imperative. Here, we report
a solvation tuning strategy by utilizing molecular steric effect to
create a “bulky coordinating” structure. Based on this
strategy, the designed electrolyte generates an inorganic-rich solid
electrolyte interphase (SEI) and cathode–electrolyte interphase
(CEI), leading to excellent compatibility with both Li metal anodes
and high-voltage cathodes. Under an ultrahigh voltage of 4.6 V, Li/NMC811
full-cells (N/P = 2.0) hold an 84.1%
capacity retention over 150 cycles and industrial Li/NMC811 pouch
cells realize an energy density of 495 Wh kg–1.
This study provides innovative insights into Li+ solvation
tuning for electrolyte engineering and offers a promising path toward
developing high-energy Li metal batteries.
Li metal is regarded as the most promising battery anode to boost energy density. However, being faced with the hostile compatibility between the Li anode and traditional carbonate electrolyte, its large-scale industrialization has been in a distressing circumstance due to severe dendrite growth caused by unsatisfying solid electrolyte interphase (SEI). With this regard, accurate control over the composition of the SEI is urgently desired to tackle the electrochemical and mechanical instability at the electrolyte/anode interface. Herein, we report a rationally designed fluorinated carbamate-based electrolyte employing LiNO 3 as one of the main salts to induce the preferable anion decomposition to achieve a homogeneous and inorganic (LiF, Li 3 N, Li 2 O)-rich SEI. Thus, this electrolyte achieves a high Coulombic efficiency of 99% of the Li metal anode, a stable cycling over 1000 h for Li|Li symmetric cells, more than 100 cycles in 40-μm-thin Li|high-loading-NCM811 full batteries, and >50 cycles in Cu|LiFePO 4 pouch cells, which is a promising electrolyte for highly reversible Li metal batteries.
Improved durability, enhanced interfacial stability, and room temperature applicability are desirable properties for all‐solid‐state lithium metal batteries (ASSLMBs), yet these desired properties are rarely achieved simultaneously. Here, in this work, it is noticed that the huge resistance at Li metal/electrolyte interface dominantly impeded the normal cycling of ASSLMBs especially at around room temperature (<30 °C). Accordingly, a supramolecular polymer ion conductor (SPC) with “weak solvation” of Li+ was prepared. Benefiting from the halogen‐bonding interaction between the electron‐deficient iodine atom (on 1,4‐diiodotetrafluorobenzene) and electron‐rich oxygen atoms (on ethylene oxide), the O‐Li+ coordination was significantly weakened. Therefore, the SPC achieves rapid Li+ transport with high Li+ transference number, and importantly, derives a unique Li2O‐rich SEI with low interfacial resistance on lithium metal surface, therefore enabling stable cycling of ASSLMBs even down to 10 °C. This work is a new exploration of halogen‐bonding chemistry in solid polymer electrolyte and highlights the importance of “weak solvation” of Li+ in the solid‐state electrolyte for room temperature ASSLMBs.
Improved durability, enhanced interfacial stability, and room temperature applicability are desirable properties for all‐solid‐state lithium metal batteries (ASSLMBs), yet these desired properties are rarely achieved simultaneously. Here, in this work, it is noticed that the huge resistance at Li metal/electrolyte interface dominantly impeded the normal cycling of ASSLMBs especially at around room temperature (<30 °C). Accordingly, a supramolecular polymer ion conductor (SPC) with “weak solvation” of Li+ was prepared. Benefiting from the halogen‐bonding interaction between the electron‐deficient iodine atom (on 1,4‐diiodotetrafluorobenzene) and electron‐rich oxygen atoms (on ethylene oxide), the O‐Li+ coordination was significantly weakened. Therefore, the SPC achieves rapid Li+ transport with high Li+ transference number, and importantly, derives a unique Li2O‐rich SEI with low interfacial resistance on lithium metal surface, therefore enabling stable cycling of ASSLMBs even down to 10 °C. This work is a new exploration of halogen‐bonding chemistry in solid polymer electrolyte and highlights the importance of “weak solvation” of Li+ in the solid‐state electrolyte for room temperature ASSLMBs.
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