Key components in a traditional lithium-ion battery include an anode, electrolyte, separator and cathode. They all work together to shuttle electrons between an EV’s charge and discharge cycles. The ...

While EVs offer environmental benefits during their operational life, these benefits diminish when batteries reach their ...

A microbial electrochemical technology capable of recovering 90%–95% of lithium from spent lithium-ion batteries has been ...

Battery energy storage systems (BESS) are revolutionizing how energy is managed. These systems are critical for improving ...

Energy storage systems (ESS) are critical for grid stability as renewable energy adoption accelerates, but safety concerns ...

LLZO-based solid-state batteries show limited energy density gains and face production challenges; hybrid electrolytes may be ...

We've long relied on lithium-ion batteries for long-term energy storage, but they can be expensive to produce and maintain ...

Australasian firms Li-S Energy and Kea Aerospace have signed a collaboration agreement to test lithium-sulphur batteries in ...

Li-S Energy has signed a collaboration agreement with Kea Aerospace (Kea) to integrate Li-S' advanced lithium sulfur battery ...

Batteries not only contain rare earth materials, but also have "forever chemicals" in their cathode and the electrolyte.

A new Bi2O3/rGO composite boosts lithium-sulfur battery performance at -60?°C. Learn how this material enhances Li2S ...

Li-S Energy has signed a collaboration agreement with Kea Aerospace to integrate Li-S’s advanced lithium sulfur battery ...