In the decade since LCLS produced its first light, it has pushed boundaries in countless areas of discovery.

SLAC researchers say their new method could make it easier to study interactions of ultrabright X-rays with matter

X-ray laser snapshots give scientists a new tool for probing trillionths-of-a-second atomic motions in 2-D materials

Using an X-ray laser, researchers watched atoms rotate on the surface of a material that was demagnetized in millionths of a billionth of a second.

Revealed for the first time by a new X-ray laser technique, their surprisingly unruly response has profound implications for designing and controlling materials.

The annual conference for scientists who conduct research at SLAC’s light sources engaged about 470 researchers in talks, workshops and discussions.

This summer, five graduate students from the University of Puerto Rico had the opportunity to use SLAC’s world-class facilities to keep their studies on track.

Their work will deepen our understanding of matter in extreme conditions and fundamental particle physics.

By observing changes in materials as they’re being synthesized, scientists hope to learn how they form and come up with recipes for making the materials they need for next-gen energy technologies.

Tais Gorkhover, Michael Kagan, Kazuhiro Terao and Joshua Turner will each receive $2.5 million for research that studies fundamental particles, nanoscale objects, quantum materials and machine learning.

By placing the tiniest strands of proteins on one-atom-thick graphene, scientists capture promising X-ray laser images of these elusive biomolecules that play a key role in neurodegenerative diseases.

Like turning a snowball back into fluffy snow, a new technique turns high-density materials into a lower-density one by applying the chemical equivalent of ‘negative pressure.’