Devereaux was honored for contributions to materials science and was among seven Stanford-affiliated researchers named AAAS Fellows this year.

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

Researchers have discovered that crystals can twist when they are sandwiched between two substrates – a critical step toward exploring new material properties for electronics and other applications.

Strongly interacting electrons in quantum materials carry heat and charge in a way that’s surprisingly similar to what individual electrons do in normal metals, a SLAC/Stanford study finds.

The American Physical Society recognized the SLAC and Stanford physicist for decades of groundbreaking work studying the strange behavior of electrons at the interfaces between materials.

The research reveals the potential for machine learning in understanding the complex behavior of quantum materials.

A groundbreaking study shows defects spreading through diamond faster than the speed of sound 

Analyzing X-ray movies with computer vision reveals how nanoparticles in a lithium-ion battery electrode work.

It irons out wrinkles in thin films of these novel superconductors so scientists can see their true nature for the first time. 

New SLAC-Stanford Battery Center bridges the gaps between discovering, manufacturing and deploying innovative energy storage solutions. 

This ‘beautiful’ herringbone-like pattern could give rise to unique features that scientists are just starting to explore.

The SIMES investigator was cited for his singular contributions to quantum materials science.