As a prospective next‐generation energy storage solution, lithium–sulfur batteries excel at
their economical attractiveness (sulfur abundance) and electrochemical performance (high …

Research on next‐generation battery technologies (beyond Li‐ion batteries, or LIBs) has
been accelerating over the past few years. A key challenge for these emerging batteries has …

Lithium–sulfur batteries are a major focus of academic and industrial energy‐storage
research due to their high theoretical energy density and the use of low‐cost materials. The …

Sulfur cathode offers a high theoretical specific capacity of 1,675 mAh g− 1 and a high
specific energy of 2,600 Wh kg− 1 when implemented in lithium-sulfur batteries (LSBs) …

Abstract Lithium–sulfur (Li–S) batteries are one of the most promising next‐generation
energy storage systems due to their ultrahigh theoretical specific capacity. However, their …

Commercial lithium-ion (Li-ion) batteries built with Ni-and Co-based intercalation-type
cathodes suffer from low specific energy, high toxicity and high cost. A further increase in the …

The development of advanced energy storage systems is of crucial importance to meet the
ever-growing demands of electric vehicles, portable devices, and renewable energy harvest …

Lithium‑sulfur (Lisingle bondS) batteries possess a significantly higher theoretical capacity
compared to lithium-ion batteries, along with several advantages such as abundant sulfur …

Separators in batteries have a great influence on their performance and safety, where both
the properties of the separator and the separator–electrode interfaces affect ion diffusion …

Li‐ion and Li–S batteries find enormous applications in different fields, such as electric
vehicles and portable electronics. A separator is an indispensable part of the battery design …