Metal batteries, with active metals as anodes, are considered as one of the most promising solutions to achieve the energy upgrade of battery technologies, yet their practical applications are ...

Glia (light green) respond to the loss of dendrite cilia (dark pink) by accumulating excess extracellular matrix (dark green). Neurons may get all the glory, but they would be nothing without glial ...

Neurons may get all the glory, but they would be nothing without glial cells. While brain cells do the heavy lifting in the ...

Lithium-ion batteries have revolutionized the way we power our gadgets, and they even nabbed the Nobel Prize in Chemistry this year. But scientists want to make even more powerful versions. Replacing ...

Neurons may get all the glory, but they would be nothing without glial cells. While brain cells do the heavy lifting in the nervous system, it's the glia that provide nutrients, clean up waste, and ...

Scientists have uncovered a root cause of the growth of needle-like structures -- known as dendrites and whiskers -- that plague lithium batteries, sometimes causing a short circuit, failure, or even ...

Dendrites are a problem in lithium-based rechargeable batteries. Over the many charge/discharge cycles, these tiny crystal growths form naturally on the lithium surface and create a kind of branching ...

New research on nematodes reveals how glial cells maintain and monitor neuronal dendrites. Neurons may get all the glory, but they would be nothing without glial cells. While brain cells do the heavy ...