SLAC topics

Stanford Institute for Materials & Energy Sciences (SIMES) RSS feed

SIMES researchers study complex, novel materials that could transform the energy landscape by making computing much more efficient or transmitting power over long distances with no loss, for instance.

Visit SIMES website

Polarons, bubbles of distortion in a perovskite lattice.

News Feature

The results cap 15 years of detective work aimed at understanding how these materials transition into a superconducting state where they can conduct electricity...

Conceptual illlustration showing a beam of light entering from the right and hitting a material, ejecting a sphere representing an electron
News Feature

Cryo-EM snapshots of the solid-electrolyte interphase, or SEI, reveal its natural swollen state and offer a new approach to lithium-metal battery design.

A battery's liquid electrolyte clings to small holes in a cryo-EM sample holder.
News Feature

Islands of inactive lithium creep like worms to reconnect with their electrodes, restoring a battery’s capacity and lifespan.

Conceptual illustration shows an EKG-like pulse of energy flatlining as it enters a battery, then coming back to life as it exits
News Feature

Topological insulators conduct electricity on their surfaces but not through their interiors. SLAC scientists discovered that high harmonic generation produces a unique signature from...

A counterclockwise pattern of swirling arrows This pattern of arrows representing the combined spin and momentum of electrons in the surface layer of a topological insulator
News Feature

Spawned by the spins of electrons in magnetic materials, these tiny whirlpools behave like independent particles and could be the future of computing. Experiments...

Illustration of skyrmions -- little whirlpools of magnetism formed by the spins of atoms.
News Feature

Much like crystallizing rock candy from sugar syrup, the new method grows 2D perovskites precisely layered with other 2D materials to produce crystals with...

Illustration of layers of 2D materials assembling themselves from chemicals tumbling in water
News Feature

The chemically controlled chains reveal an ultrastrong attraction between electrons that may help cuprate superconductors carry electrical current with no loss at relatively high...

An illustration showing a 1D chain of carbon and oxygen molecules with red springs representing natural vibrations in their atomic lattice.
News Feature

Anchoring individual iridium atoms on the surface of a catalytic particle boosted its performance in carrying out a reaction that’s been a bottleneck for...

Illustration showing surface of a catalyst as a lattice work of atoms, with single iridium molecules held above it on tiny 8-sided structures to facilitate splitting of water molecules seen floating above
News Feature

Nickelate materials give scientists an exciting new window into how unconventional superconductors carry electric current with no loss at relatively high temperatures.

Illustration showing nickelate and cuprate superconductors as cartoon characters that are either close friends holding hands or neighbors talking over a fence.
News Feature

Measuring the process in unprecedented detail gives them clues to how to minimize the problem and protect battery performance.

Illustration of oxygen atoms leaving a lithium-ion battery as lithium flows in alongside a battery whose energy is being sapped by this process
News Feature

With a new suite of tools, scientists discovered exactly how tiny plate-like catalyst particles carry out a key step in that conversion – the...

Illustration of nanoscale catalyst particles.
News Feature

It’s an example of how surprising properties can spontaneously emerge in complex materials – a phenomenon scientists hope to harness for novel technologies.

Illustration of a 2D superconducting state emerging in a 3D superconductor