The microelectronics that power daily life and speed discoveries in science and technology are the focus of a bold new vision to make them more energy efficient and able to operate in extreme environments.

Researchers across the lab are developing AI tools to harness data and particle beams in real time and make molecular movies, speeding up the discovery process in the era of big data.

A study reveals an ultrathin material’s ability to circularly polarize light, potentially informing how they work in optoelectronic devices.

Improvements to the lab’s “electron camera” use AI and “time stamping” to help reveal nature’s speedy processes more accurately. 

Researchers have uncovered new insights about tungsten's ability to conduct heat, which could lead to materials advancements for fusion reactor and aerospace technologies.

The results  could lead to a better understanding of reactions with vital roles in chemistry and biology. 

Proving the technique works puts scientists one step closer to unraveling the mysteries of hydrogen transfers.

The results should further our understanding of similar reactions with vital roles in chemistry, such as the production of vitamin D in our bodies.

An extension of the Stanford Research Computing Facility will host several data centers to handle the unprecedented data streams that will be produced by a new generation of scientific projects.