Better superconductors from ceramic copper oxides
Riccardo Comin seeks to elucidate the microscopic physics of high-temperature superconducting devices to advance their technological applications.
Riccardo Comin seeks to elucidate the microscopic physics of high-temperature superconducting devices to advance their technological applications.
Using new “quantum emulator,” physicists can observe individual atoms moving through these materials, and measure their speed.
MIT researchers have demonstrated that a tungsten ditelluride-based transistor combines two different electronic states of matter.
When rotated at a "magic angle," graphene sheets can form an insulator or a superconductor.
New technique manipulates atoms into antiferromagnetic state.
Scientists invent technique to map energy and momentum of electrons beneath a material’s surface.
Newly-appointed Assistant Professor Zach Hartwig's mission is to use nuclear technology to benefit society and the environment.
Master's candidate explores ways to cool high-temperature superconductors used in fusion research.
A quest to understand superconductivity leads MIT theoretical physicist Senthil Todadri to discoveries about new magnetic materials called quantum spin liquids.
MIT researchers propose a new method for verifying the existence of a theoretical quasiparticle.
Combining two thin-film materials yields surprising room-temperature magnetism.
MIT postdoc Cui-Zu Chang makes a spintronic breakthrough in the Moodera group.
Step-by-step, the Moodera Research Group is building the essential knowledge and hardware for next-generation quantum computers.
MIT physics graduate student Sagar Vijay co-develops error correction method for quantum computing based on special electronic states called Majorana fermions.