Are flexible electrodes suitable for Next-Generation wearable lithium-ion batteries?

Authors to whom correspondence should be addressed. Flexible electrodes are highly desirable for next-generation wearable lithium-ion batteries. To achieve high-capacity flexible electrode materials, SnO 2 with high theoretical capacity has been introduced into electrodes and shows promising capacity.

What are flexible lithium ion batteries?

The research in high performance flexible lithium ion batteries (FLIBs) thrives with the increasing demand in novel flexible electronics such as wearable devices and implantable medical kits. FLIBs share the same working mechanism with traditional LIBs. Meanwhile, FLIBs need to exhibit flexibility and even bendable and stretchable features.

Are free-standing electrodes suitable for flexible batteries?

Free-standing electrodes without any conductive agents or binders are attractive for use in flexible batteries due to their noteworthy properties, such as low cost, high conductivity, and easy ion and electron transport. Cutting-edge research supports the importance of electrospun nanofibre-based materials for various applications.

What is the role of a flexible electrode in a battery?

(i) The flexible electrode is an essential part of flexible batteries, and their roles contain transporting electrons, providing electrode reaction interfaces, supporting battery structures, and realizing flexible properties. The flexible electrode material has a decisive influence on the battery's energy density, rate performance, and flexibility.

How to create highly flexible lithium metal batteries (LMBS)?

Hence, to create highly flexible LMBs, it is necessary to explore novel forms of Li metal electrodes that exhibit robustness when subjected to deformation, such as bending, folding, and twisting. Passivated Li powders (PLPs) have several advantages as an anode material for flexible lithium metal batteries (LMBs).

What is a flexible electrode for quasi-solid-state batteries?

A flexible, lightweight electrode for quasi-solid-state batteries was developed by stacking molecularly coupled titania sheets (Ti 3 C 2) with CNTs. The electrode demonstrated high flexibility and could be repeatedly folded into any shapes.