As a member of a collaborative team led by General Atomics, SLAC will help bridge basic research programs with the growing fusion industry. 

Scientists studying laser-plasma proton acceleration made an unexpected breakthrough, simultaneously resolving multiple long-standing problems although they had only aimed to address one. 

The microelectronics that power daily life and speed discoveries in science and technology are the focus of a bold new vision to make them more energy efficient and able to operate in extreme environments.

Harnessing nuclear fusion would bring the clean, unlimited energy of the stars to Earth.

David Cesar, Julia Gonski and W.L. Kimmy Wu will each receive $2.75 million issued over five years for their research in X-ray and ultrafast science, new physics and primordial gravitational waves.

Following the NIF ignition demonstrations, the prospect of developing a fusion energy source using lasers looks brighter than ever. 

Seen in atomic detail, the seemingly smooth flow of ions through a battery’s electrolyte is a lot more complicated.

The research could lead to a better understanding of how metals behave under extreme conditions, which will aid in the development of more resilient materials. 

A new experiment suggests that this exotic precipitation forms at even lower pressures and temperatures than previously thought and could influence the unusual magnetic fields of Neptune and Uranus.

SLAC will partner in two collaborations that aim to speed up progress in fusion energy science and technology.

What could smaller particle accelerators look like in the future? SLAC scientists are working on innovations that could give more researchers access to accelerator science.

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