Researchers discovered that adding two chemicals to the electrolyte of a lithium metal battery prevents the formation of dendrites – “fingers” of lithium that pierce the barrier between the battery’s halves, causing it to short out, overheat and sometimes burst...

Results from SIMES theorists pave the way for experiments that create and control new forms of matter with light.

SIMES principal investigators Zhi-Xun Shen, Shoucheng Zhang and Aharon Kapitulnik were elected to the National Academy of Sciences.

SLAC study of tiny nanocrystals provides new insight on the design and function of nanomaterials

Two new research projects support the Stanford Institute for Materials and Energy Sciences in the study of exotic new materials that could enable future innovative electronic and photonic applications.

Stanford and SLAC engineers observed electrons at work during catalytic reactions. Their findings challenge long-held theories about some catalysts, opening the door to new or improved renewable energy applications.

SLAC study shows the so-called ‘pseudogap’ hoards electrons that otherwise might pair up to carry current through a material with 100 percent efficiency.

A study at the Department of Energy’s SLAC National Accelerator Laboratory suggests for the first time how scientists might deliberately engineer superconductors that work at higher temperatures.

Ultimate Goal: A Super-efficient Way to Conduct Electricity at Room Temperature

SLAC scientists are among the researchers to receive funding to advance solar cells, batteries, renewable fuels and bioenergy.

Rapid Charging and Draining Doesn’t Damage Lithium Ion Electrode as Much as Thought

By observing how hydrogen is absorbed into individual palladium nanocubes, Stanford materials scientists have detailed a key step in storing energy and information in nanomaterials.