The lab is responding to the coronavirus crisis by imaging disease-related biomolecules, developing standards for reliable coronavirus testing and enabling other essential research.

Researchers have squeezed a high-energy electron beam into tight bundles using terahertz radiation, a promising advance in watching the ultrafast world of atoms unfold.

SLAC scientists and collaborators are developing 3D copper printing techniques to build accelerator components.

Called XLEAP, the new method will provide sharp views of electrons in chemical processes that take place in billionths of a billionth of a second and drive crucial aspects of life.

Early-career physicist Jonathan LeyVa helps build one of the world’s most sensitive dark matter detectors.

Two projects will look for ways to link individual quantum devices into networks for quantum computing and ultrasensitive detectors.

SLAC/Stanford scientists and their colleagues find a new way to efficiently convert CO2 into the building block for sustainable liquid fuels.

At SLAC’s FACET facility, researchers have produced an intense electron beam by 'sneaking’ electrons into plasma, demonstrating a method that could be used in future compact discovery machines that explore the subatomic world.

The SLAC scientists will each receive $2.5 million for their research on fusion energy and advanced radiofrequency technology.

Four large meshes made from 2 miles of metal wire will extract potential signals of dark matter particles.

SLAC completed its work on ComCam, a commissioning device to be installed in Chile later this year.

Building the Large Synoptic Survey Telescope also means solving extraordinary technological challenges.