Topic: Materials science | SLAC National Accelerator Laboratory

Illustration

Studies of atomic-level processes that drain battery life and efficiency help improve battery performance.

Illustration

Perovskites’ unusual response to light could explain the high efficiency of these next-generation solar cell materials.

Illustration

Scientists use a series of magnets to transform an electron bunch into a narrow current spike which then produces a very intense attosecond X-ray...

Illustration

The ultrafast, ultrabright X-ray pulses of the Linac Coherent Light Source (LCLS) have enabled unprecedented views of a catalyst in action, an important step...

Illustration

Ultra-bright X-ray laser pulses can be used to strip electrons away from atoms, creating ions with strong charges.

Press Release

Studying a material that even more closely resembles the composition of ice giants, researchers found that oxygen boosts the formation of diamond rain.

News Feature

Spiraling laser light reveals how topological insulators lose their ability to conduct electric current on their surfaces.

Against a black background, thin, glowing red wires at top impinge on the hexagonal surface of a translucent mass. Small white dots travel along the edges of the surface in two directions. Within the mass, two orange cones meet at their tips.

News Feature

Waves of magnetic excitation sweep through this exciting new material whether it’s in superconducting mode or not – another possible clue to how unconventional...

A brightly colored top is seen spinning between two layers of gray, purple and red spheres representing atoms in a nickel oxide superconductor.

Illustration

A muon, center, spins like a top within the atomic lattice of a thin film of superconducting nickelate.

A brightly colored top is seen spinning between two layers of gray, purple and red spheres representing atoms in a nickel oxide superconductor. The top represents a fundamental particle called a muon.

News Feature

Researchers discover they contain a phase of quantum matter, known as charge density waves, that’s common in other unconventional superconductors. In other ways, though...

Artist's illustration shows quantum states called superconductivity and charge density waves atop an atomic lattice of balls and sticks

SLAC Science Explained

Molecular movie-making is both an art and a science; the results let us watch how nature works on the smallest scales.

News Feature

How quickly a battery electrode decays depends on properties of individual particles in the battery – at first. Later on, the network of particles...

A group of particles, some highlighted in reds and oranges to show which have begun to break apart.

Studies of atomic-level processes that drain battery life and efficiency help improve battery performance.

Perovskites’ unusual response to light could explain the high efficiency of these next-generation solar cell materials.

Scientists use a series of magnets to transform an electron bunch into a narrow current spike which then produces a very intense attosecond X-ray flash.

The ultrafast, ultrabright X-ray pulses of the Linac Coherent Light Source (LCLS) have enabled unprecedented views of a catalyst in action, an important step in the effort to develop cleaner and more efficient energy sources.

Ultra-bright X-ray laser pulses can be used to strip electrons away from atoms, creating ions with strong charges.

Studying a material that even more closely resembles the composition of ice giants, researchers found that oxygen boosts the formation of diamond rain.

Spiraling laser light reveals how topological insulators lose their ability to conduct electric current on their surfaces.

Waves of magnetic excitation sweep through this exciting new material whether it’s in superconducting mode or not – another possible clue to how unconventional superconductors carry electric current with no loss.

A muon, center, spins like a top within the atomic lattice of a thin film of superconducting nickelate.

Researchers discover they contain a phase of quantum matter, known as charge density waves, that’s common in other unconventional superconductors. In other ways, though, they’re surprisingly unique.

Molecular movie-making is both an art and a science; the results let us watch how nature works on the smallest scales.

How quickly a battery electrode decays depends on properties of individual particles in the battery – at first. Later on, the network of particles matters more.

Who we are

SLAC science explained

Vera C. Rubin Observatory LSST

Diversity, Equity & Inclusion

Shocking to the Core: Adventures in Earth Science

Materials science

Battery life and efficiency

Perovskites

XLEAP illustration

Chemical reaction

“Supercharging” atoms with X-ray laser

‘Diamond rain’ on giant icy planets could be more common than previously thought

Exploring quantum electron highways with laser light

Study finds nickelate superconductors are intrinsically magnetic

A muon spins like a top

A new leap in understanding nickel oxide superconductors

XFELs: Spying on atoms and molecules

What drives rechargeable battery decay? Depends on how many times you've charged it

Battery life and efficiency

Perovskites

XLEAP illustration

Chemical reaction

“Supercharging” atoms with X-ray laser

‘Diamond rain’ on giant icy planets could be more common than previously thought

Exploring quantum electron highways with laser light

Study finds nickelate superconductors are intrinsically magnetic

A muon spins like a top

A new leap in understanding nickel oxide superconductors

XFELs: Spying on atoms and molecules

What drives rechargeable battery decay? Depends on how many times you've charged it