Stanford Institute for Materials & Energy Sciences (SIMES)
SIMES researchers study complex, novel materials that could transform the energy landscape by making computing much more efficient or transmitting power over long distances with no loss, for instance.
An illustration shows polarons – fleeting distortions in a material’s atomic lattice ––in a promising next-generation energy material, lead hybrid perovskite.
(Greg Stewart/SLAC National Accelerator Laboratory)
These stripes of electron spin and charge are exciting because of their possible link to a phenomenon that could transform society by making electrical...
Research with SLAC’s X-ray laser simulates what happens when a meteor hits Earth’s crust. The results suggest that scientists studying impact sites have been...
Clothing made from a reversible fabric, developed in part by SIMES researchers, could warm or cool wearers and keep them comfortable, bringing down buildings’...
Extraordinarily precise measurements -- within millionths of a billionth of a second and a billionth of a hair's breadth -- show this ‘electron-phonon coupling’...
These stripes of electron spin and charge are exciting because of their possible link to a phenomenon that could transform society by making electrical transmission nearly 100 percent efficient.
Research with SLAC’s X-ray laser simulates what happens when a meteor hits Earth’s crust. The results suggest that scientists studying impact sites have been overestimating the sizes of the meteors that made them.
Clothing made from a reversible fabric, developed in part by SIMES researchers, could warm or cool wearers and keep them comfortable, bringing down buildings’ energy costs.
Extraordinarily precise measurements -- within millionths of a billionth of a second and a billionth of a hair's breadth -- show this ‘electron-phonon coupling’ can be far stronger than predicted, and could potentially play a role in unconventional superconductivity.