Peter earned a Bachelor of Archeology and Creative Writing from the University of Alabama and has since joined his love of driving and riding with storytelling. His voice is full of southern ...

The field of lithium-oxygen battery research is advancing rapidly as scientists explore avenues to capitalise on the ultra-high theoretical energy density offered by this technology. Researchers are ...

A lithium-air battery generates electricity by allowing lithium ions (Li⁺) to move from the lithium anode through the electrolyte to the porous cathode, where they react with oxygen from the air to ...

A research team develops manganese-based cathodes with longer lifespan by suppressing oxygen release. A research team led by Professor Jihyun Hong from the Department of Battery Engineering Department ...

Relay Orbital Hybridization Boosts Lithium–Oxygen Battery Catalysis. Schematic illustration of phosphorus-doped MnMoO₄ hollow nanospheres enabling “relay orbital hybridization.” Internal Mo–P orbital ...

This schematic illustrates how atomic-scale Ni catalysts embedded in a porous graphene matrix address key challenges in Li–O₂ batteries. By simultaneously enhancing cathode reaction kinetics and ...

A battery electrolyte that is solid at normal temperatures yet still conducts ions could make lithium batteries safer and longer lasting by replacing flammable liquids.

Electric vehicles have raced ahead on performance and price, but their batteries still struggle with durability, charging ...

Still or sparkling? Either way, the problem of scale remains Lithium-ion batteries are everywhere, and recycling them cleanly and safely at scale is still hard. Now, a Chinese research team claims to ...

Researchers from Harbin Institute of Technology (Shenzhen) and Johannes Gutenberg University Mainz have created a dual-function catalyst material that tackles two significant limitations in Li-O 2 ...

A nanoscale silver treatment could be the key to making solid‑state batteries viable. Stanford University researchers report ...