Electrolytes have recently regained significant attention in rechargeable batteries due to the
discovery that the electrolyte microstructures play a determinant role in battery performance …

As the demand for electric vehicles and other high-energy-density energy storage grows,
traditional graphite anodes are not sufficient to meet future needs. Lithium metal batteries …

Electrolyte is critical for transporting lithium‐ion (Li+) in lithium‐ion batteries (LIBs). However,
there is no universally applicable principle for designing an optimal electrolyte. In most …

Electrolyte design has become ever more important to enhance the performance of lithium‐
ion batteries (LIBs). However, the flammability issue and high reactivity of the conventional …

High‐voltage lithium metal batteries are the most promising energy storage technology due
to their excellent energy density (> 400 Wh kg− 1). However, the oxidation decomposition of …

Current lithium-ion batteries degrade under high rates and low temperatures due to the use
of carbonate electrolytes with restricted Li+ conduction and sluggish Li+ desolvation. Herein …

The difficulties to identify the rate‐limiting step cause the lithium (Li) plating hard to be
completely avoided on graphite anodes during fast charging. Therefore, Li plating regulation …

Reversible lithium-ion (de) intercalation in the carbon-based anodes using ethylene
carbonate (EC) based electrolytes has enabled the commercialization of lithium-ion …

Solid‐state lithium metal batteries (LMBs), constructed through the in situ fabrication of
polymer electrolytes, are considered a critical strategy for the next‐generation battery …

Ether-based electrolytes have been extensively utilized in lithium metal batteries due to their
superior compatibility with lithium metal. Nevertheless, the inferior high-voltage oxidation …