Abstract Lithium–sulfur (Li–S) batteries are regarded as the most promising next‐generation
energy storage systems due to their high energy density and cost‐effectiveness. However …

Exploring highly foldable batteries with no safety hazard is a crucial task for the realization of
portable, wearable, and implantable electric devices. Given these concerns, developing …

High energy density solid‐state lithium batteries require good ionic conductive solid
electrolytes (SE) and stable matching with high‐voltage electrode materials. Here, a highly …

Composite polymer electrolytes (CPEs) have great commercialization potential because
they can take advantage of the properties of inorganic and polymer electrolytes, which …

The extremely low room-temperature ionic conductivity of solid-state polymer electrolytes
(SPEs) ranging from 10− 7 to 10− 5 S cm− 1 seriously restricts their practical application in …

Boosting the ultralow temperature (below− 30° C) performance of Na‐ion hybrid capacitors
(SIHCs), which integrate the high energy density of batteries with the high output power and …

Artificial solid-electrolyte interlayers (SEIs) are extensively used to improve the chemical
interfacial stability at the Li/solid state electrolyte (SSE) interface. However, severe …

Solid‐state lithium batteries have become the focus of the next‐generation high‐safety
lithium batteries due to their dimensional, thermal, and electrochemical stability. Thus, the …

Incompatible interphases resulting from the irreconcilable contradiction between impedance
and mechanical strength have become one of the major obstacles to the practical …

Lithium–sulfur batteries (LSBs) hold great promise as one of the next‐generation power
supplies for portable electronics and electric vehicles due to their ultrahigh energy density …