First two-dimensional material that performs as both topological insulator and superconductor
MIT researchers have demonstrated that a tungsten ditelluride-based transistor combines two different electronic states of matter.
MIT researchers have demonstrated that a tungsten ditelluride-based transistor combines two different electronic states of matter.
Efficient method for making single-atom-thick, wafer-scale materials opens up opportunities in flexible electronics.
When rotated at a "magic angle," graphene sheets can form an insulator or a superconductor.
Summer Scholar Jennifer Coulter works on computer simulations with associate professor of materials science Alfredo Alexander-Katz.
Four new projects and one renewal receive $150,000 in funding for 2016-2017.
Method to stack hundreds of nanoscale layers could open new vistas in materials science.
Researchers demonstrate room-temperature ferroelectric states in ultra-thin films of tin and tellurium.
Some “forbidden” light emissions are in fact possible, could enable new sensors and light-emitting devices.
By slowing down light to a speed slower than flowing electrons, researchers create a kind of optical “sonic boom.”
Study points the way to new photonic devices with one-way traffic lanes.
Experimental physicist explores the wild frontiers of graphene and other ultrathin materials.
Depositing different materials within a single chip layer could lead to more efficient computers.
Diamond spintronics and graphene-based infrared detectors are among leading-edge technologies reported at annual Materials Day Symposium at MIT.
Jeffrey Grossman applies new materials research to making desalination cheaper and more efficient.
MIT-led team develops method for scaling up production of thin electronic material.