Strongly interacting electrons in quantum materials carry heat and charge in a way that’s surprisingly similar to what individual electrons do in normal metals, a SLAC/Stanford study finds.

Teams at SLAC installed new experimental hutches with cutting-edge instruments that will harness the upgraded facility’s new capabilities and expand the breadth of research done at the facility.

Disabling those hinges could be a good strategy for designing vaccines and treatments against a broad range of coronavirus infections.

The team reduced the amount of expensive platinum group metals needed to make an effective cell and found a new way to test future fuel cell innovations.

Four engineers discuss their journeys to working at SLAC and counsel those following in their footsteps.

The future of experimental particle physics is exciting –  and energy intensive. SLAC physicists are thinking about how to make one proposal, the Cool Copper Collider, more sustainable.

The American Physical Society recognized the SLAC and Stanford physicist for decades of groundbreaking work studying the strange behavior of electrons at the interfaces between materials.

The Secretary celebrated LCLS-II first light with 600 SLAC staff and collaborators Oct. 26.

LaserNetUS funding will allow scientists to explore fundamental plasma science and inertial fusion energy research and technology.

A   swap of metals and a mutation ramp up the electric field strength at the active site of an enzyme, making it   works an astonishing 50 times faster than its unmodified analog.