Spawned by the spins of electrons in magnetic materials, these tiny whirlpools behave like independent particles and could be the future of computing. Experiments with SLAC’s X-ray laser are revealing their secrets.

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

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

Known as “pair-density waves,” it may be key to understanding how superconductivity can exist at relatively high temperatures.

For decades Z-X Shen has ridden a wave of curiosity about the strange behavior of electrons that can levitate magnets.

Theory suggests that quantum critical points may be analogous to black holes as places where all sorts of strange phenomena can exist in a quantum material. Now scientists are trying to pin down where this particular quantum critical point might...

Q-NEXT will tackle next-generation quantum science challenges through a public-private partnership, ensuring U.S. leadership in an economically crucial arena.

Discovered at SLAC and Stanford, this new class of unconventional superconductors is starting to give up its secrets – including a surprising 3D metallic state.

It reveals an abrupt transition in cuprates where particles give up their individuality. The results flip a popular theory on its head.

Computer simulations yield a much more accurate picture of these states of matter.

The Hubbard model, used to understand electron behavior in numerous quantum materials, now shows us its stripes, and superconductivity too, in simulations for cuprate superconductors.