Materials science

The method could lead to the development of new materials with tailored properties, with potential applications in fields such as climate change, quantum computing and drug design.

A study reveals an ultrathin material’s ability to circularly polarize light, potentially informing how they work in optoelectronic devices.

The SLAC/Stanford researcher is a leading materials scientist and entrepreneur whose research is paving the way for better batteries, cleaner power grids.

Harold Hwang and Tony Heinz were among 124 newly elected members.

Election to the academy honors exceptional scholars who discover and advance knowledge and who apply knowledge to the problems of society.

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

The team developed a groundbreaking method that harnesses the structure of light to twist and tweak the properties of quantum materials. 

Researchers have uncovered new insights about tungsten's ability to conduct heat, which could lead to materials advancements for fusion reactor and aerospace technologies.

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

The research could lead to a better understanding of how metals behave under extreme conditions, which will aid in the development of more resilient materials. 

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.