World's most powerful X-ray laser set for massive upgrade that will help us better understand the atomic world

Scientists could soon probe the secrets of the smallest particles in the world in more detail than ever before following a major upgrade of the most powerful laser of its kind in the world.

The U.S. Department of Energy (DOE) has given the go-ahead to upgrade the Linac Coherent Light Source (LCLS), an incredibly powerful X-ray laser used for research. This is based at the SLAC National Accelerator Laboratory — located just off the Stanford University campus in the San Francisco Bay Area.

Scientists use the LCLS to document and analyze the building blocks of the universe by blasting atoms, nanostructures and molecules with X-rays. This lets them document the atomic processes that govern how the world works, and is especially useful for probing subatomic processes in quantum, energy and biological sciences.

Free-electron lasers like this produce brilliant light across an incredibly wide wavelength, with beams that are orders of magnitude brighter and more intense than other lasers. LCSC works by speeding up electrons to a velocity approaching the speed of light and then concentrating them through an array of magnets known as an "undulator." This forces them to release photons (particles of light) in a concentrated, bright beam that illuminates particles in a process akin to supercharged X-ray imaging.

How the LCSC X-ray laser works

The LCLS is housed in a 2-mile (3.2-kilometer) tunnel originally used for a particle accelerator built in 1962. It was first upgraded in 2023 as part of the "LCLS-II" project. New hardware added to the laser increased its brightness — resulting in a beam up to 10,000 times brighter than with the first phase of LCLS. LCSC-II is also one trillion times brighter than X-rays you might find in a hospital. It shoots beams in bursts of up to one million pulses per second — each lasting only a handful of femtoseconds — the time it takes light to Travel 300 nanometers (or approximately the width of a virus).

This lets it shoot frame-by-frame "movies" of chemical processes: in 2015, this allowed scientists to view how chemical bonds form for the first time, and in 2023 to observe the real-time steps of photosynthesis. This helps us understand everything from chemical reactions to the conservation of energy in novel solar cells.

Part of the project saw a new superconducting accelerator added, which greatly increased the acceleration speed of electrons within the laser. Achieving these results meant cooling the path of the particles to near absolute zero using 37 cryogenic modules (cryomodules), which lowered temperatures within the LCLS to -456 degrees F (-271 degrees C) — that’s colder than deep space.