She is recognized for two decades of innovation and excellence at the Stanford Synchrotron Radiation Lightsource.

A new study shows how soccer ball-shaped molecules burst more slowly than expected when blasted with an X-ray laser beam.

Using SLAC’s X-ray synchrotron SSRL, Wang improves fundamental knowledge about how cells communicate, which could enable the development of more effective drugs.

Combined with the lab’s LCLS X-ray laser, it’ll provide unprecedented atomic views of some of nature’s speediest processes.

A close-up look at how microbes build their crystalline shells has implications for understanding how cell structures form, preventing disease and developing nanotechnology.

X-rays reveal an extinct mouse was dressed in brown to reddish fur on its back and sides and had a tiny white tummy.

Researchers produced an underwater sound with an intensity that eclipses that of a rocket launch while investigating what happens when they blast tiny jets of water with X-ray laser pulses.

Stanford virologists are working with scientists at the new Stanford-SLAC Cryo-Electron Microscopy facility to take a new look at how herpesviruses infect cells.

A better understanding of how these receptors work could enable scientists to design better therapeutics for sleep disorders, cancer and Type 2 diabetes.

First direct look at how atoms move when a ring-shaped molecule breaks apart could boost our understanding of fundamental processes of life.

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

Researchers will use SLAC’s X-ray light source to probe 150-million-year-old dinosaur fossils at the atomic level.