Microporous membrane separators (MMS) are at the heart of rechargeable lithium/sodium
ion batteries (LIBs/NIBs) because they prevent short circuits and serve as a channel for ion …

For the practical use of synthetic hydrogels as artificial biological tissues, flexible electronics,
and conductive membranes, achieving requirements for specific mechanical properties is …

The emerging direction toward the ever-growing market of wearable electronics has
contributed to the progress made in energy storage systems that are flexible while …

Substituting liquid electrolytes with solid electrolytes is considered as an important strategy
to solve the problem of flammability and explosion for traditional lithium-ion batteries (LIB) …

As the most abundant and renewable biopolymer, cellulose has found applications in a
range of fields such as healthcare, packaging, electronics and environmental remediation …

The extreme deformation and external damage of electrolyte materials during the working
period limit its further development in flexible wearable electronics. Thus, the polyurethane …

Elastomers offer attractive advantages over classical solid‐state electrolytes in terms of
ensuring stable interfacial contact and maintaining fatigue durability, but the low ionic …

Most of the separators used in commercial rechargeable batteries are polypropylene and
polyethylene, which have the characteristics of high mechanical strength and good chemical …

Siloxane‐based molecular material, by virtue of its unique chemical structure, thermal and
electrochemical properties, has triggered tremendous research interest and sparked a …

The mobility of molecular shuttles inside a mechanically interlocked polymer (MIP) can
improve the ionic conductivity and electron transport capacity of a solid polymer electrolyte …