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

Lithium–sulfur batteries (LSBs) possess many fold higher energy densities than
conventional batteries; however, their establishment as a dominant niche in modern …

Summary Lithium-sulfur (Li-S) batteries promise high energy density for next-generation
energy storage systems, yet many challenges remain. Li-S batteries follow a conversion …

The complex interplay and only partial understanding of the multi-step phase transitions and
reaction kinetics of redox processes in lithium–sulfur batteries are the main stumbling blocks …

Fundamental understanding of solvent's influence on Li–S redox reactions is required for
rational design of electrolyte for Li–S batteries. Here we employ operando UV–vis …

Inspired by the first rechargeable Mg battery about 20 years ago, based on a Chevrel phase
cathode, a Mg foil anode, and a magnesium organo‐aluminate electrolyte, research on …

BATTERY 2030+ targets the development of a chemistry neutral platform for accelerating the
development of new sustainable high‐performance batteries. Here, a description is given of …

Magnesium–sulfur batteries are considered as attractive energy-storage devices due to the
abundance of electrochemically active materials and high theoretical energy density. Here …

Replacement of conventional cars with battery electric vehicles (BEVs) offers an opportunity
to significantly reduce future carbon dioxide emissions. One possible way to facilitate …

Rechargeable lithium–sulfur (Li–S) batteries have recently attracted global research interest
due to their high theoretical specific capacity and energy density. To improve the …