Energy‐dense rechargeable batteries have enabled a multitude of applications in recent
years. Moving forward, they are expected to see increasing deployment in performance …

The inherent technical challenges of lithium–sulfur (Li–S) batteries have arisen from the
intrinsic redox electrochemistry occurring on the Li and S electrodes, which can significantly …

The design of nanostructured electrocatalysts with high activity and long‐term durability for
the sluggish lithium polysulfide (LiPS) conversion reaction is essential for the development …

Research interest in sulfur cathode employed in lithium sulfur battery (LSB) has been greatly
aroused since 2009 due to its inherently high theoretical capacity and likely low …

Advanced energy storage systems require high energy and power densities, abundant
availability of raw materials, low cost, reasonable safety, and environmental benignancy …

Since the resurgence of interest in lithium–sulfur (Li–S) batteries at the end of the 2000s,
research in the field has grown rapidly. Li–S batteries hold great promise as the upcoming …

Abstract Lithium–sulfur (Li–S) batteries with high theoretical energy density are promising
next-generation green energy storage devices. However, the severe shuttling and …

Lithium–sulfur batteries have low material costs and high energy densities, which have
attracted considerable research interest for application in next-generation energy-storage …

Lithium–sulfur batteries are considered a possible next-generation energy-storage solution,
but their commercial viability is still in question because of several technical challenges …

Lithium–sulfur (Li–S) batteries are strong contenders among lithium batteries due to superior
capacity and energy density, but the polysulfide shuttling effect limits the cycle life and …