Stanford PULSE Institute

Using SLAC’s X-ray laser, researchers have made detailed 3-D images of nanoscale biology, with future applications in the study of air pollution, combustion and catalytic processes.

In experiments with the lab’s ultrafast "electron camera," laser light hitting a material is almost completely converted into nuclear vibrations, which are key to switching a material’s properties on and off for future electronics and other applications.

This novel method could shrink the equipment needed to make laser pulses billionths of a billionth of a second long for studying ultra-speedy electron movements in solids, chemical reactions and future electronics.

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

SLAC’s ultrafast “electron camera” reveals unusual atomic motions that could be crucial for the efficiency of next-generation perovskite solar cells.

The research team was able to watch energy from light flow through atomic ripples in a molecule. Such insights may provide new ways to develop a class of materials that improve efficiency and reduce the size of applications like solar...

A new X-ray laser technique allows scientists to home in on these single-electron triggers to better understand organic molecules that respond to light, including receptors in your eyes, plastic products and DNA building blocks that need to protect themselves from...

Aaron Lindenberg, associate professor at Stanford and SLAC, talks about how he combines X-ray and electron techniques to understand and engineer novel materials.

PULSE scientist Amy Cordones-Hahn describes her work on chemical reactions that turn sunlight into useable energy.

Physicist Phil Bucksbaum gives a brief introduction to Femtosecond Week at SLAC.

SLAC celebrates five days of ultrafast science.

Join us for five days of ultrafast science from April 17 to 21.