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.

A new way to observe this deformation as it happens can help study a wide range of phenomena, from meteor impacts to high-performance ceramics used in armor, as well as how to protect spacecraft from high-speed dust impacts.

Effort to improve the next generation of gravitational wave detectors includes atomic studies of new and better coatings for LIGO’s mirrors at SSRL.

He is recognized for his numerous contributions to the advancement of accelerator physics, community service and education.

About 400 people attended the annual conference and workshops for scientists who conduct experiments at SLAC’s light sources.

The early career award from SLAC’s X-ray laser recognizes Kjaer’s work in ultrafast X-ray science.

More than 100 students worked on projects ranging from website development to imaging techniques for X-ray studies, learning new ways to apply their talents.

A new “two-bucket” method of delivering pairs of X-ray pulses gives a 1,000-fold improvement in seeing magnetic fluctuations that could lead to improved data storage materials.

SLAC’s X-ray laser and Matter in Extreme Conditions instrument allow researchers to examine the exotic precipitation in real time as it materializes in the laboratory.

With SLAC’s X-ray laser, scientists captured a virus changing shape and rearranging its genome to invade a cell.

Tripling the energy and refining the shape of optical laser pulses at LCLS’s Matter in Extreme Conditions instrument allows researchers to recreate higher-pressure conditions and explore unsolved questions relevant to fusion energy, plasma physics and materials science.

Over the next five years they’ll work on getting significantly more information about how catalysts work and improving biological imaging methods.